/*
    This file is part of darktable,
    Copyright (C) 2011-2021 darktable developers.

    darktable is free software: you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    darktable is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with darktable.  If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdint.h>

#include "bauhaus/bauhaus.h"
#include "common/atomic.h"
#include "common/darktable.h"
#include "common/debug.h"
#include "common/histogram.h"
#include "common/iop_profile.h"
#include "common/imagebuf.h"
#include "common/image_cache.h"
#include "common/math.h"
#include "control/conf.h"
#include "control/control.h"
#include "develop/develop.h"
#include "dtgtk/button.h"
#include "dtgtk/togglebutton.h"
#include "gui/accelerators.h"
#include "gui/color_picker_proxy.h"
#include "gui/draw.h"
#include "gui/gtk.h"
#include "libs/lib.h"
#include "libs/lib_api.h"
#include "libs/colorpicker.h"
#include "common/splines.h"

#ifdef GDK_WINDOWING_QUARTZ
#include "osx/osx.h"
#endif

#define HISTOGRAM_BINS 256
// # of gradations between each primary/secondary to draw the hue ring
// this is tuned to most degenerate cases: curve to blue primary in
// Luv in linear ProPhoto RGB and the widely spaced gradations of the
// PQ P3 RGB colorspace. This could be lowered to 32 with little
// visible consequence.
#define VECTORSCOPE_HUES 48
#define VECTORSCOPE_BASE_LOG 30

DT_MODULE(1)

typedef enum dt_lib_histogram_highlight_t
{
  DT_LIB_HISTOGRAM_HIGHLIGHT_NONE = 0,
  DT_LIB_HISTOGRAM_HIGHLIGHT_BLACK_POINT,
  DT_LIB_HISTOGRAM_HIGHLIGHT_EXPOSURE
} dt_lib_histogram_highlight_t;

typedef enum dt_lib_histogram_scope_type_t
{
  DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM = 0,
  DT_LIB_HISTOGRAM_SCOPE_WAVEFORM,
  DT_LIB_HISTOGRAM_SCOPE_PARADE,
  DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE,
  DT_LIB_HISTOGRAM_SCOPE_N // needs to be the last one
} dt_lib_histogram_scope_type_t;

typedef enum dt_lib_histogram_scale_t
{
  DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC = 0,
  DT_LIB_HISTOGRAM_SCALE_LINEAR,
  DT_LIB_HISTOGRAM_SCALE_N // needs to be the last one
} dt_lib_histogram_scale_t;

typedef enum dt_lib_histogram_orient_t
{
  DT_LIB_HISTOGRAM_ORIENT_HORI = 0,
  DT_LIB_HISTOGRAM_ORIENT_VERT,
  DT_LIB_HISTOGRAM_ORIENT_N // needs to be the last one
} dt_lib_histogram_orient_t;

typedef enum dt_lib_histogram_vectorscope_type_t
{
  DT_LIB_HISTOGRAM_VECTORSCOPE_CIELUV = 0,   // CIE 1976 u*v*
  DT_LIB_HISTOGRAM_VECTORSCOPE_JZAZBZ,
  DT_LIB_HISTOGRAM_VECTORSCOPE_RYB,
  DT_LIB_HISTOGRAM_VECTORSCOPE_N // needs to be the last one
} dt_lib_histogram_vectorscope_type_t;

// FIXME: are these lists available from the enum/options in darktableconfig.xml?
const gchar *dt_lib_histogram_scope_type_names[DT_LIB_HISTOGRAM_SCOPE_N] = { "histogram", "waveform", "rgb parade", "vectorscope" };
const gchar *dt_lib_histogram_scale_names[DT_LIB_HISTOGRAM_SCALE_N] = { "logarithmic", "linear" };
const gchar *dt_lib_histogram_orient_names[DT_LIB_HISTOGRAM_ORIENT_N] = { "horizontal", "vertical" };
const gchar *dt_lib_histogram_vectorscope_type_names[DT_LIB_HISTOGRAM_VECTORSCOPE_N] = { "u*v*", "AzBz", "RYB" };

typedef struct dt_lib_histogram_t
{
  // histogram for display
  uint32_t *histogram;
  uint32_t histogram_max;
  // waveform buffers and dimensions
  uint8_t *waveform_img[3];           // image per RGB channel
  int waveform_bins, waveform_tones, waveform_max_bins;
  // FIXME: make dt_lib_histogram_vectorscope_t for all this data?
  uint8_t *vectorscope_graph, *vectorscope_bkgd;
  float vectorscope_pt[2];            // point colorpicker position
  GSList *vectorscope_samples;        // live samples position
  int selected_sample;                // position of the selected live sample in the list
  int vectorscope_diameter_px;
  float hue_ring[6][VECTORSCOPE_HUES][2] DT_ALIGNED_ARRAY;
  const dt_iop_order_iccprofile_info_t *hue_ring_prof;
  dt_lib_histogram_scale_t hue_ring_scale;
  dt_lib_histogram_vectorscope_type_t hue_ring_colorspace;
  double vectorscope_radius;
  dt_pthread_mutex_t lock;
  GtkWidget *scope_draw;               // GtkDrawingArea -- scope, scale, and draggable overlays
  GtkWidget *button_box;               // GtkButtonBox -- contains scope control buttons
  GtkWidget *button_stack;             // GtkStack -- flips between red and colorspace buttons
  GtkWidget *scope_type_button;        // GtkButton -- histogram/waveform/vectorscope control
  GtkWidget *scope_view_button;        // GtkButton -- how to render the current scope
  GtkWidget *red_channel_button;       // GtkToggleButton -- enable/disable processing R channel
  GtkWidget *green_channel_button;     // GtkToggleButton -- enable/disable processing G channel
  GtkWidget *blue_channel_button;      // GtkToggleButton -- enable/disable processing B channel
  GtkWidget *colorspace_button;        // GtkButton -- vectorscope colorspace
  // drag to change parameters
  gboolean dragging;
  int32_t button_down_x, button_down_y;
  float button_down_value;
  // depends on mouse position
  dt_lib_histogram_highlight_t highlight;
  // state set by buttons
  dt_lib_histogram_scope_type_t scope_type;
  dt_lib_histogram_scale_t histogram_scale;
  dt_lib_histogram_orient_t scope_orient;
  dt_lib_histogram_vectorscope_type_t vectorscope_type;
  dt_lib_histogram_scale_t vectorscope_scale;
  double vectorscope_angle;
  gboolean red, green, blue;
  float *rgb2ryb_ypp;
  float *ryb2rgb_ypp;
} dt_lib_histogram_t;

const char *name(dt_lib_module_t *self)
{
  return _("scopes");
}

const char **views(dt_lib_module_t *self)
{
  static const char *v[] = {"darkroom", "tethering", NULL};
  return v;
}

uint32_t container(dt_lib_module_t *self)
{
  return g_strcmp0(dt_conf_get_string("plugins/darkroom/histogram/panel_position"), "right") ? DT_UI_CONTAINER_PANEL_LEFT_TOP : DT_UI_CONTAINER_PANEL_RIGHT_TOP;
}

int expandable(dt_lib_module_t *self)
{
  return 0;
}

int position()
{
  return 1000;
}


static void _lib_histogram_process_histogram(dt_lib_histogram_t *const d, const float *const input,
                                             const dt_histogram_roi_t *const roi)
{
  dt_dev_histogram_collection_params_t histogram_params = { 0 };
  const dt_iop_colorspace_type_t cst = iop_cs_rgb;
  dt_dev_histogram_stats_t histogram_stats = { .bins_count = HISTOGRAM_BINS, .ch = 4, .pixels = 0 };
  uint32_t histogram_max[4] = { 0 };

  d->histogram_max = 0;
  memset(d->histogram, 0, sizeof(uint32_t) * 4 * HISTOGRAM_BINS);

  histogram_params.roi = roi;
  histogram_params.bins_count = HISTOGRAM_BINS;
  histogram_params.mul = histogram_params.bins_count - 1;

  // FIXME: for point sample, calculate whole graph and the point sample values, draw these on top of the graph
  // FIXME: set up "custom" histogram worker which can do colorspace conversion on fly -- in cases that we need to do that -- may need to add from colorspace to dt_dev_histogram_collection_params_t
  dt_histogram_helper(&histogram_params, &histogram_stats, cst, iop_cs_NONE, input, &d->histogram, FALSE, NULL);
  dt_histogram_max_helper(&histogram_stats, cst, iop_cs_NONE, &d->histogram, histogram_max);
  d->histogram_max = MAX(MAX(histogram_max[0], histogram_max[1]), histogram_max[2]);
}

static void _lib_histogram_process_waveform(dt_lib_histogram_t *const d, const float *const input,
                                            const dt_histogram_roi_t *const roi)
{
  // FIXME: for point sample, calculate whole graph and the point sample values, draw these on top of a dimmer graph
  const int sample_width = MAX(1, roi->width - roi->crop_width - roi->crop_x);
  const int sample_height = MAX(1, roi->height - roi->crop_height - roi->crop_y);

  // Use integral sized bins for columns, as otherwise they will be
  // unequal and have banding. Rely on draw to smoothly do horizontal
  // scaling. For a horizontal waveform of a 3:2 image, "landscape"
  // orientation, bin_width will generally be 4, for "portrait" it
  // will generally be 3. Note that waveform_bins varies, depending on
  // preview image width and # of bins.
  const dt_lib_histogram_orient_t orient = d->scope_orient;
  const int to_bin = orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? sample_width : sample_height;
  const size_t samples_per_bin = ceilf(to_bin / (float)d->waveform_max_bins);
  const size_t num_bins = ceilf(to_bin / (float)samples_per_bin);
  d->waveform_bins = num_bins;
  const size_t num_tones = d->waveform_tones;

  // Note that, with current constants, the input buffer is from the
  // preview pixelpipe and should be <= 1440x900x4. The output buffer
  // will be <= 360x160x3. Hence process works with a relatively small
  // quantity of data.
  size_t bin_pad;
  uint32_t *const restrict partial_binned = dt_calloc_perthread(3U * num_bins * num_tones, sizeof(uint32_t), &bin_pad);

#if defined(_OPENMP)
#pragma omp parallel for default(none) \
  dt_omp_firstprivate(input, partial_binned, roi, num_tones, num_bins, bin_pad, samples_per_bin, sample_height, sample_width, orient) \
  schedule(static)
#endif
  for(size_t y=0; y<sample_height; y++)
  {
    const float *const restrict px = DT_IS_ALIGNED((const float *const restrict)input +
                                                   4U * ((y + roi->crop_y) * roi->width));
    uint32_t *const restrict binned = dt_get_perthread(partial_binned, bin_pad);
    for(size_t x=0; x<sample_width; x++)
    {
      const size_t bin = (orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? x : y) / samples_per_bin;
      size_t tone[4] DT_ALIGNED_PIXEL;
      for_each_channel(ch, aligned(px,tone:16))
      {
        // 1.0 is at 8/9 of the height!
        const float v = (8.0f / 9.0f) * px[4U * (x + roi->crop_x) + ch];
        // Using ceilf brings everything <= 0 to bottom tone,
        // everything > 1.0f/(num_tones-1) to top tone.
        tone[ch] = ceilf(CLAMPS(v, 0.0f, 1.0f) * (num_tones-1));
      }
      for(size_t ch = 0; ch < 3; ch++)
        binned[num_tones * (ch * num_bins + bin) + tone[ch]]++;
    }
  }

  // shortcut to change from linear to display gamma -- borrow hybrid log-gamma LUT
  const dt_iop_order_iccprofile_info_t *const profile =
    dt_ioppr_add_profile_info_to_list(darktable.develop, DT_COLORSPACE_HLG_REC2020, "", DT_INTENT_PERCEPTUAL);
  // lut for all three channels should be the same
  const float *const restrict lut = DT_IS_ALIGNED((const float *const restrict)profile->lut_out[0]);
  const float lutmax = profile->lutsize - 1;
  const size_t wf_img_stride = cairo_format_stride_for_width(CAIRO_FORMAT_A8,
                                                             orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? num_bins : num_tones);

  // Every bin_width x height portion of the image is being described
  // in a 1 pixel x waveform_tones portion of the histogram.
  // NOTE: if constant is decreased, will brighten output
  // FIXME: instead of using an area-beased scale, figure out max bin count and scale to that?
  const float brightness = num_tones / 40.0f;
  const float scale = brightness / ((orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? sample_height : sample_width) * samples_per_bin);
  size_t nthreads = dt_get_num_threads();

#if defined(_OPENMP)
#pragma omp parallel for default(none) \
  dt_omp_firstprivate(d, partial_binned, bin_pad, wf_img_stride, num_bins, num_tones, orient, lut, lutmax, scale, nthreads) \
  schedule(static) collapse(3)
#endif
  for(size_t ch = 0; ch < 3; ch++)
    for(size_t bin = 0; bin < num_bins; bin++)
      for(size_t tone = 0; tone < num_tones; tone++)
      {
        uint8_t *const restrict wf_img = DT_IS_ALIGNED((uint8_t *const restrict)d->waveform_img[ch]);
        uint32_t acc = 0;
        for(size_t n = 0; n < nthreads; n++)
        {
          uint32_t *const restrict binned = dt_get_bythread(partial_binned, bin_pad, n);
          acc += binned[num_tones * (ch * num_bins + bin) + tone];
        }
        const float linear = MIN(1.f, scale * acc);
        const uint8_t display = lut[(int)(linear * lutmax)] * 255.f;
        if(orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
          wf_img[tone * wf_img_stride + bin] = display;
        else
          wf_img[bin * wf_img_stride + tone] = display;
      }

  dt_free_align(partial_binned);
}

// Inspired by "Paint Inspired Color Mixing and Compositing for Visualization" - Gossett
// http://vis.computer.org/vis2004/DVD/infovis/papers/gossett.pdf
// As the Gossett model is not reversible, we keep his cube hues
// and use them to transpose rgb <-> ryb by spline interpolation
// This model compensates the orange expansion by compressing from green to red
// unlike the model proposed by Junichi SUGITA & Tokiichiro TAKAHASHI,
// in "Computational RYB Color Model and its Applications",
// which compresses mainly the cyan colors (while also reversible)
// https://danielhaim.com/research/downloads/Computational%20RYB%20Color%20Model%20and%20its%20Applications.pdf

const float x_vtx[7] = {0.0, 0.166667, 0.333333, 0.5, 0.666667, 0.833333, 1.0};
const float rgb_y_vtx[7] = {0.0, 0.083333, 0.166667, 0.383838, 0.586575, 0.833333, 1.0};
const float ryb_y_vtx[] = {0.0, 0.333333, 0.472217, 0.611105, 0.715271, 0.833333, 1.0};

static void _ryb2rgb(const dt_aligned_pixel_t ryb, dt_aligned_pixel_t rgb, const float *ryb2rgb_ypp)
{
  dt_aligned_pixel_t HSV;
  dt_RGB_2_HSV(ryb, HSV);
  HSV[0] = interpolate_val(sizeof(x_vtx)/sizeof(float), (float *)x_vtx, HSV[0],
                           (float *)rgb_y_vtx, (float *)ryb2rgb_ypp, CUBIC_SPLINE);
  dt_HSV_2_RGB(HSV, rgb);
}

static void _rgb2ryb(const dt_aligned_pixel_t rgb, dt_aligned_pixel_t ryb, const float *rgb2ryb_ypp)
{
  dt_aligned_pixel_t HSV;
  dt_RGB_2_HSV(rgb, HSV);
  HSV[0] = interpolate_val(sizeof(x_vtx)/sizeof(float), (float *)x_vtx, HSV[0],
                           (float *)ryb_y_vtx, (float *)rgb2ryb_ypp, CUBIC_SPLINE);
  dt_HSV_2_RGB(HSV, ryb);
}

static inline float baselog(float x, float bound)
{
  // FIXME: use dt's fastlog()?
  return log1pf((VECTORSCOPE_BASE_LOG - 1.f) * x / bound) / logf(VECTORSCOPE_BASE_LOG) * bound;
}

static inline void log_scale(float *x, float *y, float r)
{
  const float h = dt_fast_hypotf(*x,*y);
  // Haven't seen a zero point in practice, but it is certainly
  // possible. Map these to zero, and CPU should predict that
  // this is unlikely.
  if(h >= FLT_MIN)
  {
    const float s = baselog(h, r) / h;
    *x *= s;
    *y *= s;
  }
}

static void _lib_histogram_vectorscope_bkgd(dt_lib_histogram_t *d, const dt_iop_order_iccprofile_info_t *const vs_prof)
{
  if(vs_prof == d->hue_ring_prof &&
     d->vectorscope_scale == d->hue_ring_scale &&
     d->vectorscope_type == d->hue_ring_colorspace)
    return;

  // Calculate "hue ring" by tracing along the edges of the "RGB cube"
  // which do not touch the white or black vertex. This should be the
  // maximum chromas. It's OK if some of the sampled points are
  // closer/further from each other. A hue ring in xy between
  // primaries and secondaries is larger than the RGB space clipped to
  // [0,1]. Note that hue ring calculation seems fast enough that it's
  // not worth caching, but the below math does not vary once it is
  // calculated for a profile.

  // To test if the hue ring represents RGB gamut of a histogram
  // profile with a given colorspace, use a test image: Set histogram
  // profile = input profile. The ideal test image is a hue/saturation
  // two dimensional gradient. This could simply be 7x3 px, bottom row
  // white, middle row R,Y,G,C,B,M,R, top row black,
  // scaled up via linear interpolation.

  const float vertex_rgb[6][4] DT_ALIGNED_PIXEL = {{1.f, 0.f, 0.f}, {1.f, 1.f, 0.f},
                                                   {0.f, 1.f, 0.f}, {0.f, 1.f, 1.f},
                                                   {0.f, 0.f, 1.f}, {1.f, 0.f, 1.f} };

  float max_radius = 0.f;
  const dt_lib_histogram_vectorscope_type_t vs_type = d->vectorscope_type;

  // chromaticities for drawing both hue ring and graph
  // NOTE: As ProPhoto's blue primary is very dark (and imaginary), it
  // maps to a very small radius in CIELuv.
  cairo_pattern_t *p = cairo_pattern_create_mesh();
  // initialize to make gcc-7 happy
  dt_aligned_pixel_t  rgb_display = { 0.f }, prev_rgb_display = { 0.f }, first_rgb_display = { 0.f };
  double px = 0., py= 0.;

  for(int k=0; k<6; k++)
  {
    dt_aligned_pixel_t delta;
    for_each_channel(ch, aligned(vertex_rgb, delta:16))
      delta[ch] = (vertex_rgb[(k+1)%6][ch] - vertex_rgb[k][ch]) / VECTORSCOPE_HUES;
    for(int i=0; i < VECTORSCOPE_HUES; i++)
    {
      dt_aligned_pixel_t rgb_scope, XYZ_D50 = { 0 }, chromaticity = { 0 };
      for_each_channel(ch, aligned(vertex_rgb, delta, rgb_scope:16))
        rgb_scope[ch] = vertex_rgb[k][ch] + delta[ch] * i;
      switch(vs_type)
      {
        case DT_LIB_HISTOGRAM_VECTORSCOPE_CIELUV:
        {
          dt_ioppr_rgb_matrix_to_xyz(rgb_scope, XYZ_D50, vs_prof->matrix_in_transposed, vs_prof->lut_in,
                                     vs_prof->unbounded_coeffs_in, vs_prof->lutsize, vs_prof->nonlinearlut);
          dt_aligned_pixel_t xyY;
          dt_XYZ_to_xyY(XYZ_D50, xyY);
          dt_xyY_to_Luv(xyY, chromaticity);
          dt_XYZ_to_Rec709_D50(XYZ_D50, rgb_display);
          break;
        }
        case DT_LIB_HISTOGRAM_VECTORSCOPE_JZAZBZ:
        {
          dt_ioppr_rgb_matrix_to_xyz(rgb_scope, XYZ_D50, vs_prof->matrix_in_transposed, vs_prof->lut_in,
                                     vs_prof->unbounded_coeffs_in, vs_prof->lutsize, vs_prof->nonlinearlut);
          dt_aligned_pixel_t XYZ_D65;
          dt_XYZ_D50_2_XYZ_D65(XYZ_D50, XYZ_D65);
          dt_XYZ_2_JzAzBz(XYZ_D65, chromaticity);
          dt_XYZ_to_Rec709_D50(XYZ_D50, rgb_display);
          break;
        }
        case DT_LIB_HISTOGRAM_VECTORSCOPE_RYB:
        {
          // get the color to be displayed
          _ryb2rgb(rgb_scope, rgb_display, d->ryb2rgb_ypp);
          const float alpha = M_PI * (0.33333 * ((float)k + (float)i / VECTORSCOPE_HUES));
          chromaticity[1] = cosf(alpha) * 0.01;
          chromaticity[2] = sinf(alpha) * 0.01;
          break;
        }
        case DT_LIB_HISTOGRAM_VECTORSCOPE_N:
          dt_unreachable_codepath();
      }

      d->hue_ring[k][i][0] = chromaticity[1];
      d->hue_ring[k][i][1] = chromaticity[2];
      const float h = dt_fast_hypotf(chromaticity[1], chromaticity[2]);
      max_radius = MAX(max_radius, h);

      // Try to represent hue in profile colorspace. Do crude gamut
      // clipping, and cairo_mesh_pattern_set_corner_color_rgb will
      // clamp.
      const float max_RGB = MAX(MAX(rgb_display[0], rgb_display[1]), rgb_display[2]);
      for_each_channel(ch, aligned(rgb_display:16))
        rgb_display[ch] = rgb_display[ch] / max_RGB;
      if(k==0 && i==0)
      {
        for_each_channel(ch, aligned(first_rgb_display, rgb_display:16))
          first_rgb_display[ch] = rgb_display[ch];
      }
      else
      {
        // Extend radii of the sectors of the mesh pattern so to the
        // way to the edge of the background. This matters
        // particularly for blue in ProPhoto, as there is a very small
        // chroma. By the time we reach the less intense colors,
        // max_radius is a reasonable value.
        if(h >= FLT_MIN)
        {
          chromaticity[1] *= max_radius / h;
          chromaticity[2] *= max_radius / h;
        }
        // triangle with 4th point set to make gradient
        cairo_mesh_pattern_begin_patch(p);
        cairo_mesh_pattern_move_to(p, 0., 0.);
        cairo_mesh_pattern_line_to(p, px, py);
        cairo_mesh_pattern_line_to(p, chromaticity[1], chromaticity[2]);
        cairo_mesh_pattern_set_corner_color_rgb(p, 0, prev_rgb_display[0], prev_rgb_display[1], prev_rgb_display[2]);
        cairo_mesh_pattern_set_corner_color_rgb(p, 1, prev_rgb_display[0], prev_rgb_display[1], prev_rgb_display[2]);
        cairo_mesh_pattern_set_corner_color_rgb(p, 2, rgb_display[0], rgb_display[1], rgb_display[2]);
        cairo_mesh_pattern_set_corner_color_rgb(p, 3, rgb_display[0], rgb_display[1], rgb_display[2]);
        cairo_mesh_pattern_end_patch(p);
      }

      px = chromaticity[1];
      py = chromaticity[2];
      for_each_channel(ch, aligned(prev_rgb_display, rgb_display:16))
        prev_rgb_display[ch] = rgb_display[ch];
    }
  }
  // last patch
  cairo_mesh_pattern_begin_patch(p);
  cairo_mesh_pattern_move_to(p, 0., 0.);
  cairo_mesh_pattern_line_to(p, px, py);
  cairo_mesh_pattern_line_to(p, d->hue_ring[0][0][0], d->hue_ring[0][0][1]);
  cairo_mesh_pattern_set_corner_color_rgb(p, 0, prev_rgb_display[0], prev_rgb_display[1], prev_rgb_display[2]);
  cairo_mesh_pattern_set_corner_color_rgb(p, 1, prev_rgb_display[0], prev_rgb_display[1], prev_rgb_display[2]);
  cairo_mesh_pattern_set_corner_color_rgb(p, 2, first_rgb_display[0], first_rgb_display[1], first_rgb_display[2]);
  cairo_mesh_pattern_set_corner_color_rgb(p, 3, first_rgb_display[0], first_rgb_display[1], first_rgb_display[2]);
  cairo_mesh_pattern_end_patch(p);

  const int diam_px = d->vectorscope_diameter_px;
  const double pattern_max_radius = hypotf(diam_px, diam_px);
  cairo_matrix_t matrix;
  cairo_matrix_init_scale(&matrix, max_radius / pattern_max_radius, max_radius / pattern_max_radius);
  cairo_matrix_translate(&matrix, -0.5*diam_px, -0.5*diam_px);
  cairo_pattern_set_matrix(p, &matrix);

  // rasterize chromaticities pattern for drawing speed
  cairo_surface_t *bkgd_surface = cairo_image_surface_create_for_data(d->vectorscope_bkgd, CAIRO_FORMAT_RGB24,
                                                                      diam_px, diam_px,
                                                                      cairo_format_stride_for_width(CAIRO_FORMAT_RGB24, diam_px));
  cairo_t *crt = cairo_create(bkgd_surface);
  cairo_set_operator(crt, CAIRO_OPERATOR_SOURCE);
  cairo_set_source(crt, p);
  cairo_paint(crt);
  cairo_surface_destroy(bkgd_surface);
  cairo_pattern_destroy(p);
  cairo_destroy(crt);

  if(d->vectorscope_scale == DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC)
    for(int k = 0; k < 6; k++)
      for(int i = 0; i < VECTORSCOPE_HUES; i++)
        // NOTE: hypotenuse is already calculated above, but not worth caching it
        log_scale(&d->hue_ring[k][i][0], &d->hue_ring[k][i][1], max_radius);

  d->vectorscope_radius = max_radius;
  d->hue_ring_prof = vs_prof;
  d->hue_ring_scale = d->vectorscope_scale;
  d->hue_ring_colorspace = d->vectorscope_type;
}

static  void _get_chromaticity(const dt_aligned_pixel_t RGB, dt_aligned_pixel_t chromaticity,
                               const dt_lib_histogram_vectorscope_type_t vs_type,
                               const dt_iop_order_iccprofile_info_t *vs_prof,
                               const float *rgb2ryb_ypp)
{
  switch(vs_type)
  {
    case DT_LIB_HISTOGRAM_VECTORSCOPE_CIELUV:
    {
      // NOTE: see for comparison/reference rgb_to_JzCzhz() in color_picker.c
      dt_aligned_pixel_t XYZ_D50;
      // this goes to the PCS which has standard illuminant D50
      dt_ioppr_rgb_matrix_to_xyz(RGB, XYZ_D50, vs_prof->matrix_in_transposed, vs_prof->lut_in,
                                 vs_prof->unbounded_coeffs_in, vs_prof->lutsize, vs_prof->nonlinearlut);
      // FIXME: do have to worry about chromatic adaptation? this assumes that the histogram profile white point is the same as PCS whitepoint (D50) -- if we have a D65 whitepoint profile, how does the result change if we adapt to D65 then convert to L*u*v* with a D65 whitepoint?
      dt_aligned_pixel_t xyY_D50;
      dt_XYZ_to_xyY(XYZ_D50, xyY_D50);
      // using D50 correct u*v* (not u'v') to be relative to the whitepoint (important for vectorscope) and as u*v* is more evenly spaced
      dt_xyY_to_Luv(xyY_D50, chromaticity);
      break;
    }
    case DT_LIB_HISTOGRAM_VECTORSCOPE_JZAZBZ:
    {
      dt_aligned_pixel_t XYZ_D50;
      // this goes to the PCS which has standard illuminant D50
      dt_ioppr_rgb_matrix_to_xyz(RGB, XYZ_D50, vs_prof->matrix_in_transposed, vs_prof->lut_in,
      vs_prof->unbounded_coeffs_in, vs_prof->lutsize, vs_prof->nonlinearlut);
      // FIXME: can skip a hop by pre-multipying matrices: see colorbalancergb and dt_develop_blendif_init_masking_profile() for how to make hacked profile
      dt_aligned_pixel_t XYZ_D65;
      // If the profile whitepoint is D65, its RGB -> XYZ conversion
      // matrix has been adapted to D50 (PCS standard) via
      // Bradford. Using Bradford again to adapt back to D65 gives a
      // pretty clean reversal of the transform.
      // FIXME: if the profile whitepoint is D50 (ProPhoto...), then should we use a nicer adaptation (CAT16?) to D65?
      dt_XYZ_D50_2_XYZ_D65(XYZ_D50, XYZ_D65);
      // FIXME: The bulk of processing time is spent in the XYZ -> JzAzBz conversion in the 2*3 powf() in X'Y'Z' -> L'M'S'. Making a LUT for these, using _apply_trc() to do powf() work. It only needs to be accurate enough to be about on the right pixel for a diam_px x diam_px plot
      dt_XYZ_2_JzAzBz(XYZ_D65, chromaticity);
      break;
    }
    case DT_LIB_HISTOGRAM_VECTORSCOPE_RYB:
    {
      dt_aligned_pixel_t RYB, rgb, HCV;
      dt_sRGB_to_linear_sRGB(RGB, rgb);
      _rgb2ryb(rgb, RYB, rgb2ryb_ypp);
      dt_RGB_2_HCV(RYB, HCV);
      const float alpha = 2.0 * M_PI * HCV[0];
      chromaticity[1] = cosf(alpha) * HCV[1] * 0.01;
      chromaticity[2] = sinf(alpha) * HCV[1] * 0.01;
      break;
    }
    case DT_LIB_HISTOGRAM_VECTORSCOPE_N:
      dt_unreachable_codepath();
  }
}

static void _lib_histogram_process_vectorscope(dt_lib_histogram_t *d, const float *const input,
                                               dt_histogram_roi_t *const roi,
                                               const dt_iop_order_iccprofile_info_t *vs_prof)
{
  const int diam_px = d->vectorscope_diameter_px;
  const dt_lib_histogram_vectorscope_type_t vs_type = d->vectorscope_type;
  const dt_lib_histogram_scale_t vs_scale = d->vectorscope_scale;

  if(!vs_prof || isnan(vs_prof->matrix_in[0][0]))
  {
    fprintf(stderr, "[histogram] unsupported vectorscope profile %i %s, it will be replaced with linear rec2020\n", vs_prof->type, vs_prof->filename);
    vs_prof = dt_ioppr_add_profile_info_to_list(darktable.develop, DT_COLORSPACE_LIN_REC2020, "", DT_INTENT_RELATIVE_COLORIMETRIC);
  }

  _lib_histogram_vectorscope_bkgd(d, vs_prof);
  // FIXME: particularly for u*v*, center on hue ring bounds rather than plot center, to be able to show a larger plot?
  const float max_radius = d->vectorscope_radius;
  const float max_diam = max_radius * 2.f;

  int sample_width = MAX(1, roi->width - roi->crop_width - roi->crop_x);
  int sample_height = MAX(1, roi->height - roi->crop_height - roi->crop_y);
  if(sample_width == 1 && sample_height == 1)
  {
    // point sample still calculates graph based on whole image
    sample_width = roi->width;
    sample_height = roi->height;
    roi->crop_x = roi->crop_y = 0;
  }

  const float *rgb2ryb_ypp = d->rgb2ryb_ypp;
  // RGB -> chromaticity (processor-heavy), count into bins by chromaticity
  // FIXME: if we do convert to histogram RGB, should it be an absolute colorimetric conversion (would mean knowing the histogram profile whitepoint and un-adapting its matrices) and then we have a meaningful whitepoint and could plot spectral locus -- or the reverse, adapt the spectral locus to the histogram profile PCS (always D50)?
  // FIXME: pre-allocate? -- use the same buffer as for waveform?
  dt_atomic_int *const restrict binned = __builtin_assume_aligned(dt_alloc_align(64, sizeof(int) * diam_px * diam_px), 64);
  memset(binned, 0, sizeof(int) * diam_px * diam_px);
  // FIXME: move verbosed interleaved comments into a method note at the start, as the code itself is succinct and clear
  // FIXME: even with getting rid of the extra profile conversion hop there's no noticeable speedup -- maybe this loop is memory bound -- if can get rid of one of the output buffers and still no speedup, consider doing more work in this loop, such as atomic binning
  // FIXME: make 2x2 averaging be conditional on preprocessor define
  // FIXME: average neighboring pixels on x but not y -- may be enough of an optimization
  const int sample_max_x = sample_width - (sample_width % 2);
  const int sample_max_y = sample_height - (sample_height % 2);
  // FIXME: if decimate/downsample, should blur before this
  // FIXME: instead of scaling, if chromaticity really depends only on XY, then make a lookup on startup of for each grid cell on graph output the minimum XY to populate that cell, then either brute-force scan that LUT, or start from position of last pixel and scan, or do an optimized search (1/2, 1/2, 1/2, etc.) -- would also find point sample pixel this way
#if defined(_OPENMP)
#pragma omp parallel for default(none) \
  dt_omp_firstprivate(input, binned, sample_max_x, sample_max_y, roi, rgb2ryb_ypp, diam_px, max_radius, max_diam, vs_prof, vs_type, vs_scale) \
  schedule(static) collapse(2)
#endif
  for(size_t y=0; y<sample_max_y; y+=2)
    for(size_t x=0; x<sample_max_x; x+=2)
    {
      // FIXME: There are unnecessary color math hops. Right now the data
      // comes into dt_lib_histogram_process() in a known profile
      // (usually from pixelpipe). Then (usually) it gets converted to
      // the histogram profile. Here it gets converted to XYZ D50 before
      // making its way to L*u*v* or JzAzBz:
      //   RGB (pixelpipe) -> XYZ(PCS, D50) -> RGB (histogram) -> XYZ (PCS, D50) -> chromaticity
      // Given that the histogram profile is "well behaved" and the
      // conversion to histogram profile is relative colorimetric, could
      // instead:
      //   RGB (pixelpipe) -> XYZ(PCS, D50) -> chromaticity
      // A catch is that pixelpipe RGB may be a CLUT profile, hence would
      // need to have an LCMS path unless histogram moves to before colorout.
      dt_aligned_pixel_t RGB = {0.f}, chromaticity;
      // FIXME: for speed, downsample 2x2 -> 1x1 here, which still should produce enough chromaticity data -- Question: AVERAGE(RGBx4) -> chromaticity, or AVERAGE((RGB -> chromaticity)x4)?
      // FIXME: could compromise and downsample to 2x1 -- may also be a bit faster than skipping rows
      const float *const restrict px = DT_IS_ALIGNED((const float *const restrict)input +
                                                     4U * ((y + roi->crop_y) * roi->width + x + roi->crop_x));
      for(size_t xx=0; xx<2; xx++)
        for(size_t yy=0; yy<2; yy++)
          for_each_channel(ch, aligned(px,RGB:16))
            RGB[ch] += px[4U * (yy * roi->width + xx) + ch] * 0.25f;

      _get_chromaticity(RGB, chromaticity, vs_type, vs_prof, rgb2ryb_ypp);
      // FIXME: we ignore the L or Jz components -- do they optimize out of the above code, or would in particular a XYZ_2_AzBz but helpful?
      if(vs_scale == DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC)
        log_scale(&chromaticity[1], &chromaticity[2], max_radius);

      // FIXME: make cx,cy which are float, check 0 <= cx < 1, then multiply by diam_px
      const int out_x = (diam_px-1) * (chromaticity[1] / max_diam + 0.5f);
      const int out_y = (diam_px-1) * (chromaticity[2] / max_diam + 0.5f);

      // clip any out-of-scale values, so there aren't light edges
      if(out_x >= 0 && out_x <= diam_px-1 && out_y >= 0 && out_y <= diam_px-1)
        dt_atomic_add_int(binned + out_y * diam_px + out_x, 1);
    }

  dt_aligned_pixel_t RGB = {0.f}, chromaticity;
  const dt_lib_colorpicker_statistic_t statistic = darktable.lib->proxy.colorpicker.statistic;
  dt_colorpicker_sample_t *sample;

  // find position of the primary sample
  sample = darktable.lib->proxy.colorpicker.primary_sample;
  memcpy(RGB, sample->scope[statistic], sizeof(dt_aligned_pixel_t));

  _get_chromaticity(RGB, chromaticity, vs_type, vs_prof, rgb2ryb_ypp);

  if(vs_scale == DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC)
    log_scale(&chromaticity[1], &chromaticity[2], max_radius);

  d->vectorscope_pt[0] = chromaticity[1];
  d->vectorscope_pt[1] = chromaticity[2];

  // if live simple visualized, find their position
  if(d->vectorscope_samples && darktable.lib->proxy.colorpicker.display_samples)
  {
    g_slist_free_full((GSList *)d->vectorscope_samples, free);
    d->vectorscope_samples = NULL;
    d->selected_sample = -1;
  }
  GSList *samples = darktable.lib->proxy.colorpicker.live_samples;
  if(samples)
  {
    const dt_colorpicker_sample_t *selected = darktable.lib->proxy.colorpicker.selected_sample;

    int pos = 0;
    for(; samples; samples = g_slist_next(samples))
    {
      sample = samples->data;
      if(sample == selected) d->selected_sample = pos;
      pos++;

      //find coordinates
      memcpy(RGB, sample->scope[statistic], sizeof(dt_aligned_pixel_t));

      _get_chromaticity(RGB, chromaticity, vs_type, vs_prof, rgb2ryb_ypp);

      if(vs_scale == DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC)
        log_scale(&chromaticity[1], &chromaticity[2], max_radius);

      float *sample_xy = (float *)calloc(2, sizeof(float));

      sample_xy[0] = chromaticity[1];
      sample_xy[1] = chromaticity[2];

      d->vectorscope_samples = g_slist_append(d->vectorscope_samples, sample_xy);
    }
  }

  // shortcut to change from linear to display gamma
  const dt_iop_order_iccprofile_info_t *const profile =
    dt_ioppr_add_profile_info_to_list(darktable.develop, DT_COLORSPACE_HLG_REC2020, "", DT_INTENT_PERCEPTUAL);
  const float *const restrict lut = DT_IS_ALIGNED((const float *const restrict)profile->lut_out[0]);
  const float lutmax = profile->lutsize - 1;
  const int out_stride = cairo_format_stride_for_width(CAIRO_FORMAT_A8, diam_px);
  uint8_t *const graph = d->vectorscope_graph;

  // FIXME: should count the max bin size, and vary the scale such that it is always 1?
  const float gain = 1.f / 30.f;
  const float scale = gain * (diam_px * diam_px) / (sample_width * sample_height);

  // loop appears to be too small to benefit w/OpenMP
  // FIXME: is this still true?
  for(size_t out_y = 0; out_y < diam_px; out_y++)
    for(size_t out_x = 0; out_x < diam_px; out_x++)
    {
      const int count = binned[out_y * diam_px + out_x];
      const float intensity = lut[(int)(MIN(1.f, scale * count) * lutmax)];
      graph[out_y * out_stride + out_x] = intensity * 255.0f;
    }

  dt_free_align(binned);
}

static void dt_lib_histogram_process(struct dt_lib_module_t *self, const float *const input,
                                     int width, int height,
                                     const dt_iop_order_iccprofile_info_t *const profile_info_from,
                                     const dt_iop_order_iccprofile_info_t *const profile_info_to)
{
  dt_times_t start;
  dt_get_times(&start);

  dt_lib_histogram_t *d = (dt_lib_histogram_t *)self->data;

  // special case, clear the scopes
  if(!input)
  {
    dt_pthread_mutex_lock(&d->lock);
    memset(d->histogram, 0, sizeof(uint32_t) * 4 * HISTOGRAM_BINS);
    d->waveform_bins = 0;
    d->vectorscope_radius = 0.f;
    dt_pthread_mutex_unlock(&d->lock);
    return;
  }

  // FIXME: scope goes black when click histogram lib colorpicker on -- is this meant to happen?
  // FIXME: scope doesn't redraw when click histogram lib colorpicker off -- is this meant to happen?
  dt_histogram_roi_t roi = { .width = width, .height = height,
                             .crop_x = 0, .crop_y = 0, .crop_width = 0, .crop_height = 0 };

  // Constraining the area if the colorpicker is active in area mode
  // FIXME: only need to do colorspace conversion below on roi
  // FIXME: if the only time we use roi in histogram to limit area is here, and whenever we use tether there is no colorpicker (true?), and if we're always doing a colorspace transform in darkroom and clip to roi during conversion, then can get rid of all roi code for common/histogram?
  // when darkroom colorpicker is active, gui_module is set to colorout
  const dt_view_t *cv = dt_view_manager_get_current_view(darktable.view_manager);
  if(cv->view(cv) == DT_VIEW_DARKROOM && darktable.lib->proxy.colorpicker.restrict_histogram)
  {
    const dt_colorpicker_sample_t *const sample = darktable.lib->proxy.colorpicker.primary_sample;
    dt_iop_color_picker_t *proxy = darktable.lib->proxy.colorpicker.picker_proxy;
    if(proxy && !proxy->module)
    {
      // FIXME: for histogram process whole image, then pull point sample #'s from primary_picker->scope_mean (point) or _mean, _min, _max (as in rgb curve) and draw them as an overlay
      // FIXME: for waveform point sample, could process whole image, then do an overlay of the point sample from primary_picker->scope_mean as red/green/blue dots (or short lines) at appropriate position at the horizontal/vertical position of sample
      if(sample->size == DT_LIB_COLORPICKER_SIZE_BOX)
      {
        roi.crop_x = MIN(width, MAX(0, sample->box[0] * width));
        roi.crop_y = MIN(height, MAX(0, sample->box[1] * height));
        roi.crop_width = width - MIN(width, MAX(0, sample->box[2] * width));
        roi.crop_height = height - MIN(height, MAX(0, sample->box[3] * height));
      }
      else if(sample->size == DT_LIB_COLORPICKER_SIZE_POINT)
      {
        roi.crop_x = MIN(width, MAX(0, sample->point[0] * width));
        roi.crop_y = MIN(height, MAX(0, sample->point[1] * height));
        roi.crop_width = width - MIN(width, MAX(0, sample->point[0] * width));
        roi.crop_height = height - MIN(height, MAX(0, sample->point[1] * height));
      }
    }
  }

  // Convert pixelpipe output in display RGB to histogram profile. If
  // in tether view, then the image is already converted by the
  // caller.
  // FIXME: do conversion in-place in the processing to save an extra buffer? -- at least for waveform, which already has to touch each pixel -- will need logic from _transform_matrix_rgb() -- or better yet a per-pixel callback within _transform_matrix_rgb()-ish code
  // FIXME: in case of vectorscope, it needs XYZ data, so skip this conversion and instead it's enough that it has input & profile_info_from -- though then we don't see the result of a relative colorimetric conversion to the histogram profile...
  float *img_display = dt_alloc_align_float((size_t)4 * width * height);
  if(!img_display) return;
  dt_ioppr_transform_image_colorspace_rgb(input, img_display, width, height,
                                          profile_info_from, profile_info_to, "final histogram");
  dt_pthread_mutex_lock(&d->lock);
  switch(d->scope_type)
  {
    case DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM:
      _lib_histogram_process_histogram(d, img_display, &roi);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_WAVEFORM:
    case DT_LIB_HISTOGRAM_SCOPE_PARADE:
      _lib_histogram_process_waveform(d, img_display, &roi);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE:
      _lib_histogram_process_vectorscope(d, img_display, &roi, profile_info_to);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_N:
      dt_unreachable_codepath();
      break;
  }
  dt_pthread_mutex_unlock(&d->lock);
  dt_free_align(img_display);

  dt_show_times_f(&start, "[histogram]", "final %s", dt_lib_histogram_scope_type_names[d->scope_type]);
}


static void _lib_histogram_draw_histogram(dt_lib_histogram_t *d, cairo_t *cr,
                                          int width, int height, const uint8_t mask[3])
{
  if(!d->histogram_max) return;
  const float hist_max = d->histogram_scale == DT_LIB_HISTOGRAM_SCALE_LINEAR ? d->histogram_max
                                                                             : logf(1.0 + d->histogram_max);
  // The alpha of each histogram channel is 1, hence the primaries and
  // overlaid secondaries and neutral colors should be about the same
  // brightness. The combined group is then drawn with an alpha, which
  // dims things down.
  cairo_save(cr);
  cairo_push_group_with_content(cr, CAIRO_CONTENT_COLOR);
  cairo_translate(cr, 0, height);
  cairo_scale(cr, width / 255.0, -(height - 10) / hist_max);
  cairo_set_operator(cr, CAIRO_OPERATOR_ADD);
  cairo_set_line_width(cr, DT_PIXEL_APPLY_DPI(1.));
  for(int k = 0; k < 3; k++)
    if(mask[k])
    {
      // FIXME: this is the last place in dt these are used -- if can eliminate, then can directly set button colors in CSS and simplify things
      set_color(cr, darktable.bauhaus->graph_colors[k]);
      dt_draw_histogram_8(cr, d->histogram, 4, k, d->histogram_scale == DT_LIB_HISTOGRAM_SCALE_LINEAR);
    }
  cairo_pop_group_to_source(cr);
  cairo_set_operator(cr, CAIRO_OPERATOR_ADD);
  cairo_paint_with_alpha(cr, 0.5);
  cairo_restore(cr);
}

static void _lib_histogram_draw_waveform(dt_lib_histogram_t *d, cairo_t *cr,
                                         int width, int height,
                                         const uint8_t mask[3])
{
  // composite before scaling to screen dimensions, as scaling each
  // layer on draw causes a >2x slowdown
  const double alpha_chroma = 0.75, desat_over = 0.75, alpha_over = 0.35;
  const int img_width = d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? d->waveform_bins : d->waveform_tones;
  const int img_height = d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? d->waveform_tones : d->waveform_bins;
  const size_t img_stride = cairo_format_stride_for_width(CAIRO_FORMAT_A8, img_width);
  cairo_surface_t *cs[3] = { NULL, NULL, NULL };
  cairo_surface_t *cst = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, img_width, img_height);

  cairo_t *crt = cairo_create(cst);
  cairo_set_operator(crt, CAIRO_OPERATOR_ADD);
  for(int ch = 0; ch < 3; ch++)
    if(mask[ch])
    {
      cs[ch] = cairo_image_surface_create_for_data(d->waveform_img[ch], CAIRO_FORMAT_A8,
                                                   img_width, img_height, img_stride);
      cairo_set_source_rgba(crt, ch==0 ? 1.:0., ch==1 ? 1.:0., ch==2 ? 1.:0., alpha_chroma);
      cairo_mask_surface(crt, cs[ch], 0., 0.);
    }
  cairo_set_operator(crt, CAIRO_OPERATOR_HARD_LIGHT);
  for(int ch = 0; ch < 3; ch++)
    if(cs[ch])
    {
      cairo_set_source_rgba(crt, ch==0 ? 1.:desat_over, ch==1 ? 1.:desat_over, ch==2 ? 1.:desat_over, alpha_over);
      cairo_mask_surface(crt, cs[ch], 0., 0.);
      cairo_surface_destroy(cs[ch]);
    }
  cairo_destroy(crt);

  // scale and write to output buffer
  cairo_save(cr);
  if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
  {
    // y=0 is at bottom of widget
    cairo_translate(cr, 0., height);
    cairo_scale(cr, (float)width/img_width, (float)-height/img_height);
  }
  else
  {
    cairo_scale(cr, (float)width/img_width, (float)height/img_height);
  }
  cairo_set_operator(cr, CAIRO_OPERATOR_ADD);
  cairo_set_source_surface(cr, cst, 0., 0.);
  cairo_paint(cr);
  cairo_surface_destroy(cst);
  cairo_restore(cr);
}

static void _lib_histogram_draw_rgb_parade(dt_lib_histogram_t *d, cairo_t *cr, int width, int height)
{
  // same composite-to-temp optimization as in waveform code above
  const double alpha_chroma = 0.85, desat_over = 0.85, alpha_over = 0.65;
  const int img_width = d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? d->waveform_bins : d->waveform_tones;
  const int img_height = d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI ? d->waveform_tones : d->waveform_bins;
  const size_t img_stride = cairo_format_stride_for_width(CAIRO_FORMAT_A8, img_width);
  cairo_surface_t *cst = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, img_width, img_height);

  cairo_t *crt = cairo_create(cst);
  // Though this scales and throws away data on each composite, it
  // appears to be fastest and least memory wasteful. The bin-wise
  // resolution will be visually equivalent to waveform.
  if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
    cairo_scale(crt, 1./3., 1.);
  else
    cairo_scale(crt, 1., 1./3.);
  for(int ch = 0; ch < 3; ch++)
  {
    cairo_surface_t *cs
      = cairo_image_surface_create_for_data(d->waveform_img[ch], CAIRO_FORMAT_A8,
                                            img_width, img_height, img_stride);
    cairo_set_source_rgba(crt, ch==0 ? 1.:0., ch==1 ? 1.:0., ch==2 ? 1.:0., alpha_chroma);
    cairo_set_operator(crt, CAIRO_OPERATOR_ADD);
    cairo_mask_surface(crt, cs, 0., 0.);
    cairo_set_operator(crt, CAIRO_OPERATOR_HARD_LIGHT);
    cairo_set_source_rgba(crt, ch==0 ? 1.:desat_over, ch==1 ? 1.:desat_over, ch==2 ? 1.:desat_over, alpha_over);
    cairo_mask_surface(crt, cs, 0., 0.);
    cairo_surface_destroy(cs);
    if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
      cairo_translate(crt, img_width, 0);
    else
      cairo_translate(crt, 0, img_height);
  }
  cairo_destroy(crt);

  cairo_save(cr);
  if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
  {
    // y=0 is at bottom of widget
    cairo_translate(cr, 0., height);
    cairo_scale(cr, (float)width/img_width, (float)-height/img_height);
  }
  else
  {
    cairo_scale(cr, (float)width/img_width, (float)height/img_height);
  }
  cairo_set_operator(cr, CAIRO_OPERATOR_ADD);
  cairo_set_source_surface(cr, cst, 0., 0.);
  cairo_paint(cr);
  cairo_surface_destroy(cst);
  cairo_restore(cr);
}

static void _lib_histogram_draw_vectorscope(dt_lib_histogram_t *d, cairo_t *cr,
                                            int width, int height)
{
  const float vs_radius = d->vectorscope_radius;
  const int diam_px = d->vectorscope_diameter_px;
  const int min_size = MIN(width, height);
  const double scale = min_size / (vs_radius * 2.);

  cairo_save(cr);

  // background
  cairo_pattern_t *p = cairo_pattern_create_radial(0.5 * width, 0.5 * height, 0.5 * min_size,
                                                   0.5 * width, 0.5 * height, 0.5 * hypot(min_size, min_size));
  cairo_pattern_add_color_stop_rgb(p, 0., darktable.bauhaus->graph_bg.red, darktable.bauhaus->graph_bg.green, darktable.bauhaus->graph_bg.blue);
  cairo_pattern_add_color_stop_rgb(p, 1., darktable.bauhaus->graph_exterior.red, darktable.bauhaus->graph_exterior.green, darktable.bauhaus->graph_exterior.blue);
  cairo_rectangle(cr, 0, 0, width, height);
  cairo_set_source(cr, p);
  cairo_fill(cr);
  cairo_pattern_destroy(p);

  // FIXME: the areas to left/right of the scope could have some data (primaries, whitepoint, scale, etc.)
  cairo_translate(cr, width / 2., height / 2.);
  cairo_rotate(cr, d->vectorscope_angle);

  // traditional video editor's vectorscope is oriented with x-axis Y
  // -> B, y-axis C -> R but CIE 1976 UCS is graphed x-axis as u (G ->
  // M), y-axis as v (B -> Y), so do that and keep to the proper color
  // math
  cairo_scale(cr, 1., -1.);

  // concentric circles as a scale
  set_color(cr, darktable.bauhaus->graph_grid);
  cairo_set_line_width(cr, DT_PIXEL_APPLY_DPI(1.));
  const float grid_radius = d->hue_ring_colorspace == DT_LIB_HISTOGRAM_VECTORSCOPE_CIELUV ? 100. : 0.01;
  for(int i = 1; i < 1.f + ceilf(vs_radius/grid_radius); i++)
  {
    float r = grid_radius * i;
    if(d->vectorscope_scale == DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC)
      r = baselog(r, vs_radius);
    cairo_arc(cr, 0., 0., r * scale, 0., M_PI * 2.);
    cairo_stroke(cr);
  }

  // chromaticities for drawing both hue ring and graph
  cairo_surface_t *bkgd_surface =
    dt_cairo_image_surface_create_for_data(d->vectorscope_bkgd, CAIRO_FORMAT_RGB24,
                                           diam_px, diam_px,
                                           cairo_format_stride_for_width(CAIRO_FORMAT_RGB24, diam_px));
  cairo_pattern_t *bkgd_pat = cairo_pattern_create_for_surface(bkgd_surface);
  // primary nodes circles may extend to outside of pattern
  cairo_pattern_set_extend(bkgd_pat, CAIRO_EXTEND_PAD);

  cairo_matrix_t matrix;
  cairo_matrix_init_translate(&matrix,
                              0.5*diam_px/darktable.gui->ppd,
                              0.5*diam_px/darktable.gui->ppd);
  cairo_matrix_scale(&matrix,
                     (double)diam_px / min_size / darktable.gui->ppd,
                     (double)diam_px / min_size / darktable.gui->ppd);
  cairo_pattern_set_matrix(bkgd_pat, &matrix);

  // FIXME: also add hue rings (monochrome/dotted) for input/work/output profiles
  // from Sobotka:
  // 1. The input encoding primaries. How dd the image start out life? What is valid data within that? What is invalid introduced by error of camera virtual primaries solving or math such as resampling an image such that negative lobes result?
  // 2. The working reference primaries. How did 1. end up in 2.? Are there negative and therefore nonsensical values in the working space? Should a gamut mapping pass be applied before work, between 1. and 2.?
  // 3. The output primaries rendition. From a selection of gamut mappings, is one required between 2. and 3.?"

  // graticule: histogram profile hue ring
  cairo_set_operator(cr, CAIRO_OPERATOR_ADD);
  cairo_push_group(cr);
  cairo_set_source(cr, bkgd_pat);
  for(int n = 0; n < 6; n++)
    for(int h=0; h<VECTORSCOPE_HUES; h++)
    {
      // note that hue_ring coords are calculated as float but converted here to double
      const float x = d->hue_ring[n][h][0];
      const float y = d->hue_ring[n][h][1];
      cairo_line_to(cr, x*scale, y*scale);
    }
  cairo_close_path(cr);
  cairo_stroke(cr);
  cairo_pop_group_to_source(cr);
  cairo_paint_with_alpha(cr, 0.4);

  // primary/secondary nodes
  for(int n = 0; n < 6; n++)
  {
    const float x = d->hue_ring[n][0][0];
    const float y = d->hue_ring[n][0][1];
    cairo_arc(cr, x*scale, y*scale, DT_PIXEL_APPLY_DPI(2.), 0., M_PI * 2.);
    cairo_set_source(cr, bkgd_pat);
    cairo_fill_preserve(cr);
    set_color(cr, darktable.bauhaus->graph_grid);
    cairo_stroke(cr);
  }

  // vectorscope graph
  // FIXME: use cairo_pattern_set_filter()?
  cairo_surface_t *graph_surface =
    dt_cairo_image_surface_create_for_data(d->vectorscope_graph, CAIRO_FORMAT_A8,
                                           diam_px, diam_px,
                                           cairo_format_stride_for_width(CAIRO_FORMAT_A8, diam_px));
  cairo_pattern_t *graph_pat = cairo_pattern_create_for_surface(graph_surface);
  cairo_pattern_set_matrix(graph_pat, &matrix);

  cairo_set_operator(cr, CAIRO_OPERATOR_ADD);

  const gboolean display_primary_sample = darktable.lib->proxy.colorpicker.restrict_histogram &&
      darktable.lib->proxy.colorpicker.primary_sample->size == DT_LIB_COLORPICKER_SIZE_POINT;
  const gboolean display_live_samples = d->vectorscope_samples &&
      darktable.lib->proxy.colorpicker.display_samples;

  if(display_primary_sample || display_live_samples)
    cairo_push_group(cr);
  cairo_set_source(cr, bkgd_pat);
  cairo_mask(cr, graph_pat);
  cairo_set_operator(cr, CAIRO_OPERATOR_HARD_LIGHT);
  cairo_set_source_rgba(cr, 1.0, 1.0, 1.0, 0.55);
  cairo_mask(cr, graph_pat);

  cairo_pattern_destroy(bkgd_pat);
  cairo_surface_destroy(bkgd_surface);
  cairo_pattern_destroy(graph_pat);
  cairo_surface_destroy(graph_surface);

  if(display_primary_sample || display_live_samples)
  {
    cairo_pop_group_to_source(cr);
    cairo_paint_with_alpha(cr, 0.5);
  }

  cairo_set_operator(cr, CAIRO_OPERATOR_OVER);

  // overlay central circle
  set_color(cr, darktable.bauhaus->graph_grid);
  cairo_set_line_width(cr, DT_PIXEL_APPLY_DPI(1.5));
  cairo_new_sub_path(cr);
  cairo_arc(cr, 0., 0., DT_PIXEL_APPLY_DPI(3.), 0., M_PI * 2.);
  cairo_fill(cr);

  if(display_primary_sample)
  {
    // point sample
    set_color(cr, darktable.bauhaus->graph_fg);
    cairo_arc(cr, scale*d->vectorscope_pt[0], scale*d->vectorscope_pt[1],
              DT_PIXEL_APPLY_DPI(3.), 0., M_PI * 2.);
    cairo_fill(cr);
  }

   // live samples
  if(display_live_samples)
  {
    GSList *samples = d->vectorscope_samples;
    float *sample_xy = NULL;
    int pos = 0;
    for( ; samples; samples = g_slist_next(samples))
    {
      sample_xy = samples->data;
      if(pos == d->selected_sample)
      {
        set_color(cr, darktable.bauhaus->graph_fg_active);
        cairo_arc(cr, scale * sample_xy[0], scale * sample_xy[1], DT_PIXEL_APPLY_DPI(6.), 0., M_PI * 2.);
        cairo_fill(cr);
      }
      else
      {
        set_color(cr, darktable.bauhaus->graph_fg);
        cairo_arc(cr, scale * sample_xy[0], scale * sample_xy[1], DT_PIXEL_APPLY_DPI(4.), 0., M_PI * 2.);
        cairo_stroke(cr);
      }
      pos++;
    }
  }

  cairo_restore(cr);
}

// FIXME: have different drawable for each scope in a stack -- simplifies this function from being a swath of conditionals -- then essentially draw callbacks _lib_histogram_draw_waveform, _lib_histogram_draw_rgb_parade, etc.
// FIXME: if exposure change regions are separate widgets, then we could have a menu to swap in different overlay widgets (sort of like basic adjustments) to adjust other things about the image, e.g. tone equalizer, color balance, etc.
static gboolean _drawable_draw_callback(GtkWidget *widget, cairo_t *crf, gpointer user_data)
{
  dt_times_t start;
  dt_get_times(&start);

  dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  dt_develop_t *dev = darktable.develop;

  GtkAllocation allocation;
  gtk_widget_get_allocation(widget, &allocation);
  const int width = allocation.width, height = allocation.height;

  cairo_surface_t *cst = dt_cairo_image_surface_create(CAIRO_FORMAT_ARGB32, width, height);
  cairo_t *cr = cairo_create(cst);

  gtk_render_background(gtk_widget_get_style_context(widget), cr, 0, 0, width, height);
  cairo_set_line_width(cr, DT_PIXEL_APPLY_DPI(.5)); // borders width

  // Draw frame and background
  if(d->scope_type != DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE)
  {
    cairo_save(cr);
    cairo_rectangle(cr, 0, 0, width, height);
    set_color(cr, darktable.bauhaus->graph_bg);
    cairo_fill(cr);
    cairo_restore(cr);
  }

  // exposure change regions
  if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_BLACK_POINT)
  {
    set_color(cr, darktable.bauhaus->graph_overlay);
    if(d->scope_type == DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM)
      cairo_rectangle(cr, 0., 0., 0.2 * width, height);
    else if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
      cairo_rectangle(cr, 0., 7.0/9.0 * height, width, height);
    else if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_VERT)
      cairo_rectangle(cr, 0., 0., 2.0/9.0 * width, height);
    else
      dt_unreachable_codepath();
    cairo_fill(cr);
  }
  else if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_EXPOSURE)
  {
    set_color(cr, darktable.bauhaus->graph_overlay);
    if(d->scope_type == DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM)
      cairo_rectangle(cr, 0.2 * width, 0., width, height);
    else if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
      cairo_rectangle(cr, 0., 0., width, 7.0/9.0 * height);
    else if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_VERT)
      cairo_rectangle(cr, 2.0/9.0 * width, 0., width, height);
    else
      dt_unreachable_codepath();
    cairo_fill(cr);
  }

  // draw grid
  set_color(cr, darktable.bauhaus->graph_grid);
  switch(d->scope_type)
  {
    case DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM:
      // FIXME: now that vectorscope grid represents log scale, should histogram grid do the same?
      dt_draw_grid(cr, 4, 0, 0, width, height);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_WAVEFORM:
    case DT_LIB_HISTOGRAM_SCOPE_PARADE:
      dt_draw_waveform_lines(cr, 0, 0, width, height,
                             d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE:
      // grid is drawn with scope, as it depends on chromaticity scale
      // FIXME: now that there is no auto-scale but logarithmic/linear, can draw grid here again?
      break;
    case DT_LIB_HISTOGRAM_SCOPE_N:
      dt_unreachable_codepath();
  }

  // FIXME: should set histogram buffer to black if have just entered tether view and nothing is displayed
  dt_pthread_mutex_lock(&d->lock);
  // darkroom view: draw scope so long as preview pipe is finished
  // tether view: draw whatever has come in from tether
  const dt_view_t *cv = dt_view_manager_get_current_view(darktable.view_manager);
  if(cv->view(cv) == DT_VIEW_TETHERING || dev->image_storage.id == dev->preview_pipe->output_imgid)
  {
    const uint8_t mask[3] = { d->red, d->green, d->blue };
    switch(d->scope_type)
    {
      case DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM:
        _lib_histogram_draw_histogram(d, cr, width, height, mask);
        break;
      case DT_LIB_HISTOGRAM_SCOPE_WAVEFORM:
        if(!d->waveform_bins) break;
        _lib_histogram_draw_waveform(d, cr, width, height, mask);
        break;
      case DT_LIB_HISTOGRAM_SCOPE_PARADE:
        if(!d->waveform_bins) break;
        _lib_histogram_draw_rgb_parade(d, cr, width, height);
        break;
      case DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE:
        if(d->vectorscope_radius != 0.f)
          _lib_histogram_draw_vectorscope(d, cr, width, height);
        break;
      case DT_LIB_HISTOGRAM_SCOPE_N:
        dt_unreachable_codepath();
    }
  }
  dt_pthread_mutex_unlock(&d->lock);

  // finally a thin border
  cairo_rectangle(cr, 0, 0, width, height);
  set_color(cr, darktable.bauhaus->graph_border);
  cairo_stroke(cr);

  cairo_destroy(cr);
  cairo_set_source_surface(crf, cst, 0, 0);
  cairo_paint(crf);
  cairo_surface_destroy(cst);

  dt_show_times_f(&start, "[histogram]", "scope draw");
  return TRUE;
}

static gboolean _drawable_motion_notify_callback(GtkWidget *widget, GdkEventMotion *event,
                                                 gpointer user_data)
{
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  dt_develop_t *dev = darktable.develop;
  GtkAllocation allocation;
  gtk_widget_get_allocation(widget, &allocation);

  if(d->dragging)
  {
    // FIXME: dragging the vectorscope could change white balance
    const gboolean width_wise = (d->scope_type == DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM ||
                                 d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_VERT);
    const float diff = width_wise ? event->x - d->button_down_x : d->button_down_y - event->y;
    const int range = width_wise ? allocation.width : allocation.height;
    // FIXME: see dt_bauhaus_slider_postponed_value_change(): delay processing until the pixelpipe can update based on dev->preview_average_delay for smoother interaction
    if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_EXPOSURE)
    {
      const float exposure = d->button_down_value + diff * 4.0f / (float)range;
      dt_dev_exposure_set_exposure(dev, exposure);
    }
    else if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_BLACK_POINT)
    {
      const float black = d->button_down_value - diff * .1f / (float)range;
      dt_dev_exposure_set_black(dev, black);
    }
  }
  else
  {
    const float x = event->x;
    const float y = event->y;
    const float posx = x / (float)(allocation.width);
    const float posy = y / (float)(allocation.height);
    const dt_lib_histogram_highlight_t prior_highlight = d->highlight;
    const dt_view_t *cv = dt_view_manager_get_current_view(darktable.view_manager);
    const gboolean hooks_available = (cv->view(cv) == DT_VIEW_DARKROOM) && dt_dev_exposure_hooks_available(dev);

    // FIXME: make just one tooltip for the widget depending on whether it is draggable or not, and set it when enter the view
    if(!hooks_available || d->scope_type == DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE)
    {
      d->highlight = DT_LIB_HISTOGRAM_HIGHLIGHT_NONE;
      gtk_widget_set_tooltip_text(widget, _("ctrl+scroll to change display height"));
    }
    // FIXME: could a GtkRange be used to do this work?
    else if((posx < 0.2f && d->scope_type == DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM) ||
            (d->scope_type == DT_LIB_HISTOGRAM_SCOPE_WAVEFORM &&
             ((posy > 7.0f/9.0f && d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI) ||
              (posx < 2.0f/9.0f && d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_VERT))))
    {
      d->highlight = DT_LIB_HISTOGRAM_HIGHLIGHT_BLACK_POINT;
      gtk_widget_set_tooltip_text(widget, _("drag to change black point,\ndoubleclick resets\nctrl+scroll to change display height"));
    }
    else
    {
      d->highlight = DT_LIB_HISTOGRAM_HIGHLIGHT_EXPOSURE;
      gtk_widget_set_tooltip_text(widget, _("drag to change exposure,\ndoubleclick resets\nctrl+scroll to change display height"));
    }
    if(prior_highlight != d->highlight)
    {
      dt_control_queue_redraw_widget(widget);
      if(d->highlight != DT_LIB_HISTOGRAM_HIGHLIGHT_NONE)
      {
        // FIXME: should really use named cursors, and differentiate between "grab" and "grabbing"
        dt_control_change_cursor(GDK_HAND1);
      }
    }
  }

  //bubble event to eventbox to update the button tooltip
  return FALSE;
}

static gboolean _drawable_button_press_callback(GtkWidget *widget, GdkEventButton *event, gpointer user_data)
{
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  dt_develop_t *dev = darktable.develop;

  if(d->highlight != DT_LIB_HISTOGRAM_HIGHLIGHT_NONE)
  {
    if(event->type == GDK_2BUTTON_PRESS)
    {
      dt_dev_exposure_reset_defaults(dev);
    }
    else
    {
      // FIXME: should change cursor from "grab" to "grabbing", but this would mean rewriting dt_control_change_cursor() to use gdk_cursor_new_from_name()
      if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_EXPOSURE)
      {
        d->button_down_value = dt_dev_exposure_get_exposure(dev);
      }
      else if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_BLACK_POINT)
      {
        d->button_down_value = dt_dev_exposure_get_black(dev);
      }
      d->dragging = TRUE;
      d->button_down_x = event->x;
      d->button_down_y = event->y;
    }
  }

  return TRUE;
}

static gboolean _drawable_scroll_callback(GtkWidget *widget, GdkEventScroll *event, gpointer user_data)
{
  if(dt_modifier_is(event->state, GDK_CONTROL_MASK))
  {
    // bubble to adjusting the overall widget size
    return FALSE;
  }
  const dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  int delta_y;
  // note are using unit rather than smooth scroll events, as
  // exposure changes can get laggy if handling a multitude of smooth
  // scroll events
  if(dt_gui_get_scroll_unit_deltas(event, NULL, &delta_y) &&
     d->highlight != DT_LIB_HISTOGRAM_HIGHLIGHT_NONE)
  {
    dt_develop_t *dev = darktable.develop;
    // FIXME: see dt_bauhaus_slider_postponed_value_change(): delay processing until the pixelpipe can update based on dev->preview_average_delay for smoother interaction
    if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_EXPOSURE)
    {
      const float ce = dt_dev_exposure_get_exposure(dev);
      dt_dev_exposure_set_exposure(dev, ce - 0.15f * delta_y);
    }
    else if(d->highlight == DT_LIB_HISTOGRAM_HIGHLIGHT_BLACK_POINT)
    {
      const float cb = dt_dev_exposure_get_black(dev);
      dt_dev_exposure_set_black(dev, cb + 0.001f * delta_y);
    }
  }

  return TRUE;
}

static gboolean _drawable_button_release_callback(GtkWidget *widget, GdkEventButton *event,
                                                  gpointer user_data)
{
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  d->dragging = FALSE;
  // hack to recalculate the highlight as mouse may be over a different part of the widget
  // FIXME: generate an event instead?
  _drawable_motion_notify_callback(widget, (GdkEventMotion *)event, user_data);
  return TRUE;
}

static gboolean _drawable_leave_notify_callback(GtkWidget *widget, GdkEventCrossing *event,
                                                gpointer user_data)
{
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  // if dragging, gtk keeps up motion notifications until mouse button
  // is released, at which point we'll get another leave event for
  // drawable if pointer is still outside of the widget
  if(!d->dragging && d->highlight != DT_LIB_HISTOGRAM_HIGHLIGHT_NONE)
  {
    d->highlight = DT_LIB_HISTOGRAM_HIGHLIGHT_NONE;
    dt_control_change_cursor(GDK_LEFT_PTR);
    dt_control_queue_redraw_widget(widget);
  }
  // event should bubble up to the eventbox
  return FALSE;
}

static void _histogram_scale_update(const dt_lib_histogram_t *d)
{
  switch(d->histogram_scale)
  {
    case DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC:
      gtk_widget_set_tooltip_text(d->scope_view_button, _("set scale to linear"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_view_button),
                             dtgtk_cairo_paint_logarithmic_scale, CPF_NONE, NULL);
      break;
    case DT_LIB_HISTOGRAM_SCALE_LINEAR:
      gtk_widget_set_tooltip_text(d->scope_view_button, _("set scale to logarithmic"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_view_button),
                             dtgtk_cairo_paint_linear_scale, CPF_NONE, NULL);
      break;
    case DT_LIB_HISTOGRAM_SCALE_N:
      dt_unreachable_codepath();
  }
  // FIXME: this should really redraw current iop if its background is a histogram (check request_histogram)
  darktable.lib->proxy.histogram.is_linear = d->histogram_scale == DT_LIB_HISTOGRAM_SCALE_LINEAR;
}

static void _scope_orient_update(const dt_lib_histogram_t *d)
{
  switch(d->scope_orient)
  {
    case DT_LIB_HISTOGRAM_ORIENT_HORI:
      gtk_widget_set_tooltip_text(d->scope_view_button, _("set scope to vertical"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_view_button),
                             dtgtk_cairo_paint_arrow, CPF_DIRECTION_DOWN, NULL);
      break;
    case DT_LIB_HISTOGRAM_ORIENT_VERT:
      gtk_widget_set_tooltip_text(d->scope_view_button, _("set scope to horizontal"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_view_button),
                             dtgtk_cairo_paint_arrow, CPF_DIRECTION_LEFT, NULL);
      break;
    case DT_LIB_HISTOGRAM_ORIENT_N:
      dt_unreachable_codepath();
  }
}

static void _vectorscope_view_update(dt_lib_histogram_t *d)
{
  switch(d->vectorscope_scale)
  {
    case DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC:
      gtk_widget_set_tooltip_text(d->scope_view_button, _("set scale to linear"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_view_button),
                             dtgtk_cairo_paint_logarithmic_scale, CPF_NONE, NULL);
      break;
    case DT_LIB_HISTOGRAM_SCALE_LINEAR:
      gtk_widget_set_tooltip_text(d->scope_view_button, _("set scale to logarithmic"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_view_button),
                             dtgtk_cairo_paint_linear_scale, CPF_NONE, NULL);
      break;
    case DT_LIB_HISTOGRAM_SCALE_N:
      dt_unreachable_codepath();
  }
  switch(d->vectorscope_type)
  {
    case DT_LIB_HISTOGRAM_VECTORSCOPE_CIELUV:
      gtk_widget_set_tooltip_text(d->colorspace_button, _("set view to AzBz"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->colorspace_button),
                             dtgtk_cairo_paint_luv, CPF_NONE, NULL);
      break;
    case DT_LIB_HISTOGRAM_VECTORSCOPE_JZAZBZ:
      gtk_widget_set_tooltip_text(d->colorspace_button, _("set view to RYB"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->colorspace_button),
                             dtgtk_cairo_paint_jzazbz, CPF_NONE, NULL);
      break;
    case DT_LIB_HISTOGRAM_VECTORSCOPE_RYB:
      gtk_widget_set_tooltip_text(d->colorspace_button, _("set view to u*v*"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->colorspace_button),
                             dtgtk_cairo_paint_ryb, CPF_NONE, NULL);
      break;
    case DT_LIB_HISTOGRAM_VECTORSCOPE_N:
      dt_unreachable_codepath();
  }
}

static void _scope_type_update(dt_lib_histogram_t *d)
{
  switch(d->scope_type)
  {
    case DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM:
      gtk_widget_set_tooltip_text(d->scope_type_button, _("set mode to waveform"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_type_button),
                             dtgtk_cairo_paint_histogram_scope, CPF_NONE, NULL);
      gtk_widget_set_sensitive(d->red_channel_button, TRUE);
      gtk_widget_set_sensitive(d->green_channel_button, TRUE);
      gtk_widget_set_sensitive(d->blue_channel_button, TRUE);
      gtk_stack_set_visible_child(GTK_STACK(d->button_stack), d->red_channel_button);
      _histogram_scale_update(d);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_WAVEFORM:
      gtk_widget_set_tooltip_text(d->scope_type_button, _("set mode to rgb parade"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_type_button),
                             dtgtk_cairo_paint_waveform_scope, CPF_NONE, NULL);
      gtk_widget_set_sensitive(d->red_channel_button, TRUE);
      gtk_widget_set_sensitive(d->green_channel_button, TRUE);
      gtk_widget_set_sensitive(d->blue_channel_button, TRUE);
      gtk_stack_set_visible_child(GTK_STACK(d->button_stack), d->red_channel_button);
      _scope_orient_update(d);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_PARADE:
      gtk_widget_set_tooltip_text(d->scope_type_button, _("set mode to vectorscope"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_type_button),
                             dtgtk_cairo_paint_rgb_parade, CPF_NONE, NULL);
      gtk_widget_set_sensitive(d->red_channel_button, FALSE);
      gtk_widget_set_sensitive(d->green_channel_button, FALSE);
      gtk_widget_set_sensitive(d->blue_channel_button, FALSE);
      gtk_stack_set_visible_child(GTK_STACK(d->button_stack), d->red_channel_button);
      _scope_orient_update(d);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE:
      gtk_widget_set_tooltip_text(d->scope_type_button, _("set mode to histogram"));
      dtgtk_button_set_paint(DTGTK_BUTTON(d->scope_type_button),
                             dtgtk_cairo_paint_vectorscope, CPF_NONE, NULL);
      gtk_widget_set_sensitive(d->red_channel_button, FALSE);
      gtk_widget_set_sensitive(d->green_channel_button, FALSE);
      gtk_widget_set_sensitive(d->blue_channel_button, FALSE);
      gtk_stack_set_visible_child(GTK_STACK(d->button_stack), d->colorspace_button);
      _vectorscope_view_update(d);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_N:
      dt_unreachable_codepath();
  }
}

static void _scope_type_clicked(GtkWidget *button, dt_lib_histogram_t *d)
{
  // NOTE: this isn't a "real" button but more of a multi-state toggle/switcher button
  d->scope_type = (d->scope_type + 1) % DT_LIB_HISTOGRAM_SCOPE_N;
  dt_conf_set_string("plugins/darkroom/histogram/mode", dt_lib_histogram_scope_type_names[d->scope_type]);
  _scope_type_update(d);

  if(d->scope_type == DT_LIB_HISTOGRAM_SCOPE_PARADE)
  {
    // waveform and RGB parade both work on the same underlying data
    dt_control_queue_redraw_widget(d->scope_draw);
  }
  else
  {
    // generate data for changed scope and trigger widget redraw
    const dt_view_t *cv = dt_view_manager_get_current_view(darktable.view_manager);
    if(cv->view(cv) == DT_VIEW_DARKROOM)
      dt_dev_process_preview(darktable.develop);
    else
      dt_control_queue_redraw_center();
  }
}

static void _scope_view_clicked(GtkWidget *button, dt_lib_histogram_t *d)
{
  switch(d->scope_type)
  {
    case DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM:
      d->histogram_scale = (d->histogram_scale + 1) % DT_LIB_HISTOGRAM_SCALE_N;
      dt_conf_set_string("plugins/darkroom/histogram/histogram",
                         dt_lib_histogram_scale_names[d->histogram_scale]);
      _histogram_scale_update(d);
      // don't need to reprocess data
      dt_control_queue_redraw_widget(d->scope_draw);
      return;
    case DT_LIB_HISTOGRAM_SCOPE_WAVEFORM:
    case DT_LIB_HISTOGRAM_SCOPE_PARADE:
      d->scope_orient = (d->scope_orient + 1) % DT_LIB_HISTOGRAM_ORIENT_N;
      dt_conf_set_string("plugins/darkroom/histogram/orient",
                         dt_lib_histogram_orient_names[d->scope_orient]);
      d->waveform_bins = 0;
      _scope_orient_update(d);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE:
      d->vectorscope_scale = (d->vectorscope_scale + 1) % DT_LIB_HISTOGRAM_SCALE_N;
      dt_conf_set_string("plugins/darkroom/histogram/vectorscope/scale",
                         dt_lib_histogram_scale_names[d->vectorscope_scale]);
      _vectorscope_view_update(d);
      break;
    case DT_LIB_HISTOGRAM_SCOPE_N:
      dt_unreachable_codepath();
  }
  // trigger new process from scratch
  const dt_view_t *cv = dt_view_manager_get_current_view(darktable.view_manager);
  if(cv->view(cv) == DT_VIEW_DARKROOM)
    dt_dev_process_preview(darktable.develop);
  else
    dt_control_queue_redraw_center();
}

static void _colorspace_clicked(GtkWidget *button, dt_lib_histogram_t *d)
{
  d->vectorscope_type = (d->vectorscope_type + 1) % DT_LIB_HISTOGRAM_VECTORSCOPE_N;
  dt_conf_set_string("plugins/darkroom/histogram/vectorscope",
                     dt_lib_histogram_vectorscope_type_names[d->vectorscope_type]);
  _vectorscope_view_update(d);
  // trigger new process from scratch depending on whether CIELuv or JzAzBz
  // FIXME: it would be nice as with other scopes to make the initial processing independent of the view
  const dt_view_t *cv = dt_view_manager_get_current_view(darktable.view_manager);
  if(cv->view(cv) == DT_VIEW_DARKROOM)
    dt_dev_process_preview(darktable.develop);
  else
    dt_control_queue_redraw_center();
}

// FIXME: these all could be the same function with different user_data
static void _red_channel_toggle(GtkWidget *button, dt_lib_histogram_t *d)
{
  d->red = gtk_toggle_button_get_active(GTK_TOGGLE_BUTTON(button));
  gtk_widget_set_tooltip_text(button, d->red ? _("click to hide red channel") : _("click to show red channel"));
  dt_conf_set_bool("plugins/darkroom/histogram/show_red", d->red);
  dt_control_queue_redraw_widget(d->scope_draw);
}

static void _green_channel_toggle(GtkWidget *button, dt_lib_histogram_t *d)
{
  d->green = gtk_toggle_button_get_active(GTK_TOGGLE_BUTTON(button));
  gtk_widget_set_tooltip_text(button, d->green ? _("click to hide green channel") : _("click to show green channel"));
  dt_conf_set_bool("plugins/darkroom/histogram/show_green", d->green);
  dt_control_queue_redraw_widget(d->scope_draw);
}

static void _blue_channel_toggle(GtkWidget *button, dt_lib_histogram_t *d)
{
  d->blue = gtk_toggle_button_get_active(GTK_TOGGLE_BUTTON(button));
  gtk_widget_set_tooltip_text(button, d->blue ? _("click to hide blue channel") : _("click to show blue channel"));
  dt_conf_set_bool("plugins/darkroom/histogram/show_blue", d->blue);
  dt_control_queue_redraw_widget(d->scope_draw);
}

static gboolean _eventbox_enter_notify_callback(GtkWidget *widget, GdkEventCrossing *event,
                                                 gpointer user_data)
{
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  gtk_widget_show(d->button_box);
  return TRUE;
}

static gboolean _eventbox_motion_notify_callback(GtkWidget *widget, GdkEventCrossing *event,
                                                 gpointer user_data)
{
  //This is required in order to correctly display the button tooltips
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
  gtk_widget_set_tooltip_text(d->green_channel_button, d->green ? _("click to hide green channel") : _("click to show green channel"));
  gtk_widget_set_tooltip_text(d->blue_channel_button, d->blue ? _("click to hide blue channel") : _("click to show blue channel"));
  gtk_widget_set_tooltip_text(d->red_channel_button, d->red ? _("click to hide red channel") : _("click to show red channel"));
  _scope_type_update(d);
  return TRUE;
}

static gboolean _eventbox_leave_notify_callback(GtkWidget *widget, GdkEventCrossing *event,
                                                 gpointer user_data)
{
  // when click between buttons on the buttonbox a leave event is generated -- ignore it
  if(!(event->mode == GDK_CROSSING_UNGRAB && event->detail == GDK_NOTIFY_INFERIOR))
  {
    dt_lib_histogram_t *d = (dt_lib_histogram_t *)user_data;
    gtk_widget_hide(d->button_box);
  }
  return TRUE;
}

static gboolean _lib_histogram_scroll_callback(GtkWidget *widget, GdkEventScroll *event, gpointer user_data)
{
  int delta_y;
  if(dt_gui_get_scroll_unit_deltas(event, NULL, &delta_y) &&
     dt_modifier_is(event->state, GDK_CONTROL_MASK) && !darktable.gui->reset)
  {
    /* set size of navigation draw area */
    const float hmin = (float)dt_confgen_get_int("plugins/darkroom/histogram/height", DT_MIN);
    const float hmax = (float)dt_confgen_get_int("plugins/darkroom/histogram/height", DT_MAX);
    const float histheight = clamp_range_f(dt_conf_get_int("plugins/darkroom/histogram/height") * 1.0f + 10 * delta_y, hmin, hmax);
    dt_conf_set_int("plugins/darkroom/histogram/height", histheight);
    gtk_widget_set_size_request(widget, -1, DT_PIXEL_APPLY_DPI(histheight));
  }
  return TRUE;
}

static gboolean _lib_histogram_collapse_callback(GtkAccelGroup *accel_group,
                                                 GObject *acceleratable, guint keyval,
                                                 GdkModifierType modifier, gpointer data)
{
  dt_lib_module_t *self = (dt_lib_module_t *)data;

  // Get the state
  const gint visible = dt_lib_is_visible(self);

  // Inverse the visibility
  dt_lib_set_visible(self, !visible);

  return TRUE;
}

static gboolean _lib_histogram_cycle_mode_callback(GtkAccelGroup *accel_group,
                                                   GObject *acceleratable, guint keyval,
                                                   GdkModifierType modifier, gpointer user_data)
{
  dt_lib_module_t *self = (dt_lib_module_t *)user_data;
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)self->data;

  // FIXME: When switch modes, this hack turns off the highlight and turn the cursor back to pointer, as we don't know what/if the new highlight is going to be. Right solution would be to have a highlight update function which takes cursor x,y and is called either here or on pointer motion. Really right solution is probably separate widgets for the drag areas which generate enter/leave events.
  d->dragging = FALSE;
  d->highlight = DT_LIB_HISTOGRAM_HIGHLIGHT_NONE;
  dt_control_change_cursor(GDK_LEFT_PTR);

  // The cycle order is Hist log -> lin -> waveform hori -> vert -> parade hori -> vert ->
  // vectorscope log u*v* -> lin u*v* -> log AzBz -> lin AzBzS (update logic on more scopes)
  switch(d->scope_type)
  {
    case DT_LIB_HISTOGRAM_SCOPE_HISTOGRAM:
      if(d->histogram_scale == DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC)
      {
        _scope_view_clicked(d->scope_view_button, d);
      }
      else
      {
        d->scope_orient = DT_LIB_HISTOGRAM_ORIENT_HORI;
        dt_conf_set_string("plugins/darkroom/histogram/orient",
                           dt_lib_histogram_orient_names[d->scope_orient]);
        _scope_type_clicked(d->scope_type_button, d);
      }
      break;
    case DT_LIB_HISTOGRAM_SCOPE_WAVEFORM:
      if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
      {
        _scope_view_clicked(d->scope_view_button, d);
      }
      else
      {
        d->scope_orient = DT_LIB_HISTOGRAM_ORIENT_HORI;
        dt_conf_set_string("plugins/darkroom/histogram/orient",
                           dt_lib_histogram_orient_names[d->scope_orient]);
        _scope_type_clicked(d->scope_type_button, d);
      }
      break;
    case DT_LIB_HISTOGRAM_SCOPE_PARADE:
      if(d->scope_orient == DT_LIB_HISTOGRAM_ORIENT_HORI)
      {
        _scope_view_clicked(d->scope_view_button, d);
      }
      else
      {
        d->vectorscope_type = DT_LIB_HISTOGRAM_VECTORSCOPE_CIELUV;
        dt_conf_set_string("plugins/darkroom/histogram/vectorscope",
                           dt_lib_histogram_vectorscope_type_names[d->vectorscope_type]);
        d->vectorscope_scale = DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC;
        dt_conf_set_string("plugins/darkroom/histogram/vectorscope/scale",
                           dt_lib_histogram_scale_names[d->vectorscope_scale]);
        _scope_type_clicked(d->scope_type_button, d);
      }
      break;
    case DT_LIB_HISTOGRAM_SCOPE_VECTORSCOPE:
      if(d->vectorscope_scale == DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC)
      {
        _scope_view_clicked(d->scope_view_button, d);
      }
      else if(d->vectorscope_type == DT_LIB_HISTOGRAM_VECTORSCOPE_CIELUV)
      {
        d->vectorscope_scale = DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC;
        dt_conf_set_string("plugins/darkroom/histogram/vectorscope/scale",
                           dt_lib_histogram_scale_names[d->vectorscope_scale]);
        _colorspace_clicked(d->colorspace_button, d);
      }
      else
      {
        d->histogram_scale = DT_LIB_HISTOGRAM_SCALE_LOGARITHMIC;
        dt_conf_set_string("plugins/darkroom/histogram/histogram",
                           dt_lib_histogram_scale_names[d->histogram_scale]);
        _scope_type_clicked(d->scope_type_button, d);
      }
      break;
    case DT_LIB_HISTOGRAM_SCOPE_N:
      dt_unreachable_codepath();
  }

  return TRUE;
}

static gboolean _lib_histogram_change_mode_callback(GtkAccelGroup *accel_group,
                                                    GObject *acceleratable, guint keyval,
                                                    GdkModifierType modifier, gpointer user_data)
{
  dt_lib_module_t *self = (dt_lib_module_t *)user_data;
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)self->data;
  d->dragging = FALSE;
  d->highlight = DT_LIB_HISTOGRAM_HIGHLIGHT_NONE;
  dt_control_change_cursor(GDK_LEFT_PTR);
  _scope_type_clicked(d->scope_type_button, d);
  return TRUE;
}

static gboolean _lib_histogram_change_type_callback(GtkAccelGroup *accel_group,
                                                    GObject *acceleratable, guint keyval,
                                                    GdkModifierType modifier, gpointer user_data)
{
  dt_lib_module_t *self = (dt_lib_module_t *)user_data;
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)self->data;
  _scope_view_clicked(d->scope_view_button, d);
  return TRUE;
}

// this is only called in darkroom view
static void _lib_histogram_preview_updated_callback(gpointer instance, dt_lib_module_t *self)
{
  // preview pipe has already given process() the high quality
  // pre-gamma image. Now that preview pipe is complete, draw it
  // FIXME: it would be nice if process() just queued a redraw if not in live view, but then our draw code would have to have some other way to assure that the histogram image is current besides checking the pixelpipe to see if it has processed the current image
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)self->data;
  dt_control_queue_redraw_widget(d->scope_draw);
}

void view_enter(struct dt_lib_module_t *self, struct dt_view_t *old_view, struct dt_view_t *new_view)
{
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)self->data;
  if(new_view->view(new_view) == DT_VIEW_DARKROOM)
  {
    DT_DEBUG_CONTROL_SIGNAL_CONNECT(darktable.signals, DT_SIGNAL_DEVELOP_PREVIEW_PIPE_FINISHED,
                              G_CALLBACK(_lib_histogram_preview_updated_callback), self);
  }
  // button box should be hidden when enter view, unless mouse is over
  // histogram, in which case gtk kindly generates enter events
  gtk_widget_hide(d->button_box);

  // FIXME: set histogram data to blank if enter tether with no active image
}

void view_leave(struct dt_lib_module_t *self, struct dt_view_t *old_view, struct dt_view_t *new_view)
{
  DT_DEBUG_CONTROL_SIGNAL_DISCONNECT(darktable.signals,
                               G_CALLBACK(_lib_histogram_preview_updated_callback),
                               self);
}

void gui_init(dt_lib_module_t *self)
{
  /* initialize ui widgets */
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)dt_calloc_align(64, sizeof(dt_lib_histogram_t));
  self->data = (void *)d;

  dt_pthread_mutex_init(&d->lock, NULL);

  d->red = dt_conf_get_bool("plugins/darkroom/histogram/show_red");
  d->green = dt_conf_get_bool("plugins/darkroom/histogram/show_green");
  d->blue = dt_conf_get_bool("plugins/darkroom/histogram/show_blue");

  const char *str = dt_conf_get_string_const("plugins/darkroom/histogram/mode");
  for(dt_lib_histogram_scope_type_t i=0; i<DT_LIB_HISTOGRAM_SCOPE_N; i++)
    if(g_strcmp0(str, dt_lib_histogram_scope_type_names[i]) == 0)
      d->scope_type = i;

  str = dt_conf_get_string_const("plugins/darkroom/histogram/histogram");
  for(dt_lib_histogram_scale_t i=0; i<DT_LIB_HISTOGRAM_SCALE_N; i++)
    if(g_strcmp0(str, dt_lib_histogram_scale_names[i]) == 0)
      d->histogram_scale = i;

  str = dt_conf_get_string_const("plugins/darkroom/histogram/orient");
  for(dt_lib_histogram_orient_t i=0; i<DT_LIB_HISTOGRAM_ORIENT_N; i++)
    if(g_strcmp0(str, dt_lib_histogram_orient_names[i]) == 0)
      d->scope_orient = i;

  str = dt_conf_get_string_const("plugins/darkroom/histogram/vectorscope");
  for(dt_lib_histogram_vectorscope_type_t i=0; i<DT_LIB_HISTOGRAM_VECTORSCOPE_N; i++)
    if(g_strcmp0(str, dt_lib_histogram_vectorscope_type_names[i]) == 0)
      d->vectorscope_type = i;

  str = dt_conf_get_string_const("plugins/darkroom/histogram/vectorscope/scale");
  for(dt_lib_histogram_scale_t i=0; i<DT_LIB_HISTOGRAM_SCALE_N; i++)
    if(g_strcmp0(str, dt_lib_histogram_scale_names[i]) == 0)
      d->vectorscope_scale = i;

  int a = dt_conf_get_int("plugins/darkroom/histogram/vectorscope/angle");
  d->vectorscope_angle = a * M_PI / 180.0;

  d->histogram = (uint32_t *)calloc(4 * HISTOGRAM_BINS, sizeof(uint32_t));
  d->histogram_max = 0;

  // Waveform buffer doesn't need to be coupled with the histogram
  // widget size. The waveform is almost always scaled when
  // drawn. Choose buffer dimensions which produces workable detail,
  // don't use too much CPU/memory, and allow reasonable gradations
  // of tone.

  // Don't use absurd amounts of memory, exceed width of DT_MIPMAP_F
  // (which will be darktable.mipmap_cache->max_width[DT_MIPMAP_F]*2
  // for mosaiced images), nor make it too slow to calculate
  // (regardless of ppd). Try to get enough detail for a (default)
  // 350px panel, possibly 2x that on hidpi.  The actual buffer
  // width will vary with integral binning of image.
  // FIXME: increasing waveform_max_bins increases processing speed less than increasing waveform_tones -- tune these better?
  d->waveform_max_bins = darktable.mipmap_cache->max_width[DT_MIPMAP_F]/2;
  // initially no waveform to draw
  d->waveform_bins = 0;
  // Should be at least 100 (approx. # of tones the eye can see) and
  // multiple of 16 (for optimization), larger #'s will make a more
  // detailed scope display at cost of a bit of CPU/memory.
  // 175 rows is the default histogram widget height. It's OK if the
  // widget height changes from this, as the width will almost always
  // be scaled. 175 rows is reasonable CPU usage and represents plenty
  // of tonal gradation. 256 would match the # of bins in a regular
  // histogram.
  d->waveform_tones = 160;
  // FIXME: combine waveform_8bit and vectorscope_graph, as only ever use one or the other
  // FIXME: keep alignment instead via single alloc via dt_alloc_perthread()?
  const size_t bytes_hori = d->waveform_tones * cairo_format_stride_for_width(CAIRO_FORMAT_A8, d->waveform_max_bins);
  const size_t bytes_vert = d->waveform_max_bins * cairo_format_stride_for_width(CAIRO_FORMAT_A8, d->waveform_tones);
  for(int ch=0; ch<3; ch++)
    d->waveform_img[ch] = dt_alloc_align(64, sizeof(uint8_t) * MAX(bytes_hori, bytes_vert));

  // FIXME: what is the appropriate resolution for this: balance memory use, processing speed, helpful resolution
  // FIXME: make this and waveform params #DEFINEd or const above, rather than set here?
  d->vectorscope_diameter_px = 384;
  d->vectorscope_graph = dt_alloc_align(64, sizeof(uint8_t) * d->vectorscope_diameter_px *
                                        cairo_format_stride_for_width(CAIRO_FORMAT_A8, d->vectorscope_diameter_px));
  d->vectorscope_bkgd = dt_alloc_align(64, sizeof(uint8_t) * 4U * d->vectorscope_diameter_px *
                                       cairo_format_stride_for_width(CAIRO_FORMAT_RGB24, d->vectorscope_diameter_px));
  d->hue_ring_prof = NULL;
  d->hue_ring_scale = DT_LIB_HISTOGRAM_SCALE_N;
  d->hue_ring_colorspace = DT_LIB_HISTOGRAM_VECTORSCOPE_N;
  // initially no vectorscope to draw
  d->vectorscope_radius = 0.f;

  // initially no live samples
  d->vectorscope_samples = NULL;
  d->selected_sample = -1;

  d->rgb2ryb_ypp = interpolate_set(sizeof(x_vtx)/sizeof(float), (float *)x_vtx, (float *)ryb_y_vtx, CUBIC_SPLINE);
  d->ryb2rgb_ypp = interpolate_set(sizeof(x_vtx)/sizeof(float), (float *)x_vtx, (float *)rgb_y_vtx, CUBIC_SPLINE);
  // proxy functions and data so that pixelpipe or tether can
  // provide data for a histogram
  // FIXME: do need to pass self, or can wrap a callback as a lambda
  darktable.lib->proxy.histogram.module = self;
  darktable.lib->proxy.histogram.process = dt_lib_histogram_process;
  darktable.lib->proxy.histogram.is_linear = d->histogram_scale == DT_LIB_HISTOGRAM_SCALE_LINEAR;

  // create widgets
  GtkWidget *overlay = gtk_overlay_new();

  // shows the scope, scale, and has draggable areas
  d->scope_draw = gtk_drawing_area_new();
  gtk_widget_set_tooltip_text(d->scope_draw, _("ctrl+scroll to change display height"));
  dt_action_define(&darktable.view_manager->proxy.darkroom.view->actions, "histogram", "hide histogram", d->scope_draw, NULL);
  gtk_widget_set_events(d->scope_draw, GDK_ENTER_NOTIFY_MASK);

  // a row of control buttons
  d->button_box = gtk_button_box_new(GTK_ORIENTATION_HORIZONTAL);
  gtk_button_box_set_layout(GTK_BUTTON_BOX(d->button_box), GTK_BUTTONBOX_EXPAND);
  gtk_widget_set_valign(d->button_box, GTK_ALIGN_START);
  gtk_widget_set_halign(d->button_box, GTK_ALIGN_END);

  // FIXME: should histogram/waveform/vectorscope each be its own widget, and a GtkStack to switch between them?

  // First two buttons choose scope type and view of that scope (if
  // applicable). On click dt_lib_histogram_t data is updated,
  // icons/tooltips are updated, and button sensitivity is set as
  // needed.

  // FIXME: the button transitions when they appear on mouseover (mouse enters scope widget) or change (mouse click) cause redraws of the entire scope -- is there a way to avoid this?
  // FIXME: this could be a combobox to allow for more types and not to have to swap the icon on click
  // icons will be filled in by _scope_type_update()
  d->scope_type_button = dtgtk_button_new(dtgtk_cairo_paint_empty, CPF_NONE, NULL);
  dt_action_define(&darktable.view_manager->proxy.darkroom.view->actions, "histogram", "switch histogram mode", d->scope_type_button, NULL);
  gtk_box_pack_start(GTK_BOX(d->button_box), d->scope_type_button, FALSE, FALSE, 0);
  d->scope_view_button = dtgtk_button_new(dtgtk_cairo_paint_empty, CPF_NONE, NULL);
  dt_action_define(&darktable.view_manager->proxy.darkroom.view->actions, "histogram", "switch histogram type", d->scope_view_button, NULL);
  gtk_box_pack_start(GTK_BOX(d->button_box), d->scope_view_button, FALSE, FALSE, 0);

  // the red togglebutton turns into colorspace button in vectorscope
  d->button_stack = gtk_stack_new();
  gtk_box_pack_start(GTK_BOX(d->button_box), d->button_stack, FALSE, FALSE, 0);

  // red/green/blue channel on/off
  // these are toggle boxes with a meaningful active state, unlike the type/view buttons
  d->red_channel_button = dtgtk_togglebutton_new(dtgtk_cairo_paint_color, CPF_NONE, NULL);
  gtk_widget_set_name(d->red_channel_button, "red-channel-button");
  gtk_widget_set_tooltip_text(d->red_channel_button, d->red ? _("click to hide red channel") : _("click to show red channel"));
  gtk_toggle_button_set_active(GTK_TOGGLE_BUTTON(d->red_channel_button), d->red);
  // FIXME: just use gtk_container_add() as don't care about name?
  gtk_stack_add_named(GTK_STACK(d->button_stack), d->red_channel_button, "red");

  d->green_channel_button = dtgtk_togglebutton_new(dtgtk_cairo_paint_color, CPF_NONE, NULL);
  gtk_widget_set_name(d->green_channel_button, "green-channel-button");
  gtk_widget_set_tooltip_text(d->green_channel_button, d->green ? _("click to hide green channel") : _("click to show green channel"));
  gtk_toggle_button_set_active(GTK_TOGGLE_BUTTON(d->green_channel_button), d->green);
  gtk_box_pack_start(GTK_BOX(d->button_box), d->green_channel_button, FALSE, FALSE, 0);

  d->blue_channel_button = dtgtk_togglebutton_new(dtgtk_cairo_paint_color, CPF_NONE, NULL);
  gtk_widget_set_name(d->blue_channel_button, "blue-channel-button");
  gtk_widget_set_tooltip_text(d->blue_channel_button, d->blue ? _("click to hide blue channel") : _("click to show blue channel"));
  gtk_toggle_button_set_active(GTK_TOGGLE_BUTTON(d->blue_channel_button), d->blue);
  gtk_box_pack_start(GTK_BOX(d->button_box), d->blue_channel_button, FALSE, FALSE, 0);

  d->colorspace_button = dtgtk_button_new(dtgtk_cairo_paint_empty, CPF_NONE, NULL);
  // FIXME: just use gtk_container_add() as don't care about name?
  gtk_stack_add_named(GTK_STACK(d->button_stack), d->colorspace_button, "colorspace");

  // will change sensitivity of channel buttons, hence must run after all buttons are declared
  _scope_type_update(d);

  // FIXME: add a brightness control (via GtkScaleButton?)

  // assemble the widgets

  // The main widget is an overlay which has no window, and hence
  // can't catch events. We need something on top to catch events to
  // show/hide the buttons. The drawable is below the buttons, and
  // hence won't catch motion events for the buttons, and gets a leave
  // event when the cursor moves over the buttons.

  // |----- EventBox -----|
  // |                    |
  // |  |-- Overlay  --|  |
  // |  |              |  |
  // |  |  ButtonBox   |  |
  // |  |              |  |
  // |  |--------------|  |
  // |  |              |  |
  // |  |  DrawingArea |  |
  // |  |              |  |
  // |  |--------------|  |
  // |                    |
  // |--------------------|

  GtkWidget *eventbox = gtk_event_box_new();
  gtk_container_add(GTK_CONTAINER(overlay), d->scope_draw);
  gtk_overlay_add_overlay(GTK_OVERLAY(overlay), d->button_box);
  gtk_container_add(GTK_CONTAINER(eventbox), overlay);
  self->widget = eventbox;

  gtk_widget_set_name(self->widget, "main-histogram");
  dt_gui_add_help_link(self->widget, dt_get_help_url(self->plugin_name));

  /* connect callbacks */

  g_signal_connect(G_OBJECT(d->scope_type_button), "clicked", G_CALLBACK(_scope_type_clicked), d);
  g_signal_connect(G_OBJECT(d->scope_view_button), "clicked", G_CALLBACK(_scope_view_clicked), d);
  g_signal_connect(G_OBJECT(d->colorspace_button), "clicked", G_CALLBACK(_colorspace_clicked), d);

  g_signal_connect(G_OBJECT(d->red_channel_button), "toggled", G_CALLBACK(_red_channel_toggle), d);
  g_signal_connect(G_OBJECT(d->green_channel_button), "toggled", G_CALLBACK(_green_channel_toggle), d);
  g_signal_connect(G_OBJECT(d->blue_channel_button), "toggled", G_CALLBACK(_blue_channel_toggle), d);

  gtk_widget_add_events(d->scope_draw, GDK_LEAVE_NOTIFY_MASK | GDK_POINTER_MOTION_MASK | GDK_BUTTON_PRESS_MASK |
                                       GDK_BUTTON_RELEASE_MASK | darktable.gui->scroll_mask);
  // FIXME: why does cursor motion over buttons trigger multiple draw callbacks?
  g_signal_connect(G_OBJECT(d->scope_draw), "draw", G_CALLBACK(_drawable_draw_callback), d);
  g_signal_connect(G_OBJECT(d->scope_draw), "leave-notify-event",
                   G_CALLBACK(_drawable_leave_notify_callback), d);
  g_signal_connect(G_OBJECT(d->scope_draw), "button-press-event",
                   G_CALLBACK(_drawable_button_press_callback), d);
  g_signal_connect(G_OBJECT(d->scope_draw), "button-release-event",
                   G_CALLBACK(_drawable_button_release_callback), d);
  g_signal_connect(G_OBJECT(d->scope_draw), "motion-notify-event",
                   G_CALLBACK(_drawable_motion_notify_callback), d);
  g_signal_connect(G_OBJECT(d->scope_draw), "scroll-event",
                   G_CALLBACK(_drawable_scroll_callback), d);

  gtk_widget_add_events(eventbox, GDK_LEAVE_NOTIFY_MASK | GDK_ENTER_NOTIFY_MASK | GDK_POINTER_MOTION_MASK);
  g_signal_connect(G_OBJECT(eventbox), "enter-notify-event",
                   G_CALLBACK(_eventbox_enter_notify_callback), d);
  g_signal_connect(G_OBJECT(eventbox), "leave-notify-event",
                   G_CALLBACK(_eventbox_leave_notify_callback), d);
  g_signal_connect(G_OBJECT(eventbox), "motion-notify-event",
                   G_CALLBACK(_eventbox_motion_notify_callback), d);

  // handles scroll-to-resize behavior
  gtk_widget_add_events(self->widget, darktable.gui->scroll_mask);
  g_signal_connect(G_OBJECT(self->widget), "scroll-event",
                   G_CALLBACK(_lib_histogram_scroll_callback), NULL);

  /* set size of histogram draw area */
  const float histheight = dt_conf_get_int("plugins/darkroom/histogram/height") * 1.0f;
  gtk_widget_set_size_request(self->widget, -1, DT_PIXEL_APPLY_DPI(histheight));
}

void gui_cleanup(dt_lib_module_t *self)
{
  dt_lib_histogram_t *d = (dt_lib_histogram_t *)self->data;

  free(d->histogram);
  for(int ch=0; ch<3; ch++)
    dt_free_align(d->waveform_img[ch]);
  dt_free_align(d->vectorscope_graph);
  dt_free_align(d->vectorscope_bkgd);
  if(d->vectorscope_samples)
    g_slist_free_full((GSList *)d->vectorscope_samples, free);
  d->vectorscope_samples = NULL;
  d->selected_sample = -1;
  dt_pthread_mutex_destroy(&d->lock);
  g_free(d->rgb2ryb_ypp);
  g_free(d->ryb2rgb_ypp);
  dt_free_align(self->data);
  self->data = NULL;
}

void init_key_accels(dt_lib_module_t *self)
{
  dt_accel_register_lib_as_view("darkroom", NC_("accel", "histogram/hide histogram"), GDK_KEY_H, GDK_CONTROL_MASK | GDK_SHIFT_MASK);
  dt_accel_register_lib_as_view("tethering", NC_("accel", "hide histogram"), GDK_KEY_H, GDK_CONTROL_MASK | GDK_SHIFT_MASK);
  dt_accel_register_lib_as_view("darkroom", NC_("accel", "histogram/cycle histogram modes"), 0, 0);
  dt_accel_register_lib_as_view("tethering", NC_("accel", "cycle histogram modes"), 0, 0);
  dt_accel_register_lib_as_view("darkroom", NC_("accel", "histogram/switch histogram mode"), 0, 0);
  dt_accel_register_lib_as_view("tethering", NC_("accel", "switch histogram mode"), 0, 0);
  dt_accel_register_lib_as_view("darkroom", NC_("accel", "histogram/switch histogram type"), 0, 0);
  dt_accel_register_lib_as_view("tethering", NC_("accel", "switch histogram type"), 0, 0);
}

void connect_key_accels(dt_lib_module_t *self)
{
  dt_accel_connect_lib_as_view(self, "darkroom", "histogram/hide histogram",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_collapse_callback), self, NULL));
  dt_accel_connect_lib_as_view(self, "tethering", "hide histogram",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_collapse_callback), self, NULL));
  dt_accel_connect_lib_as_view(self, "darkroom", "histogram/cycle histogram modes",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_cycle_mode_callback), self, NULL));
  dt_accel_connect_lib_as_view(self, "tethering", "cycle histogram modes",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_cycle_mode_callback), self, NULL));
  dt_accel_connect_lib_as_view(self, "darkroom", "histogram/switch histogram mode",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_change_mode_callback), self, NULL));
  dt_accel_connect_lib_as_view(self, "tethering", "switch histogram mode",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_change_mode_callback), self, NULL));
  dt_accel_connect_lib_as_view(self, "darkroom", "histogram/switch histogram type",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_change_type_callback), self, NULL));
  dt_accel_connect_lib_as_view(self, "tethering", "switch histogram type",
                     g_cclosure_new(G_CALLBACK(_lib_histogram_change_type_callback), self, NULL));
}

// modelines: These editor modelines have been set for all relevant files by tools/update_modelines.sh
// vim: shiftwidth=2 expandtab tabstop=2 cindent
// kate: tab-indents: off; indent-width 2; replace-tabs on; indent-mode cstyle; remove-trailing-spaces modified;
